Method of detecting at least one mechanism of resistance to carbapenems by mass spectrometry

ABSTRACT

The present invention pertains to a method of detection, by mass spectrometry, of at least one marker of at least one mechanism of resistance to at least one antimicrobial, resistance of at least one microorganism contained in a sample, characterised in that the antimicrobial is a carbapenem, and said resistance markers are proteins or peptides. Preferably, said proteins or peptides are proteins from said microorganism.

This is a Division of application Ser. No. 14/111,083 filed Oct. 10, 2013, which in turn is a national stage of PCT/EP2012/057323, filed Apr. 20, 2012, which claims the benefit of U.S. Provisional Application No. 61/477,915 filed Apr. 21, 2011. The disclosure of the prior applications is hereby incorporated by reference herein in its entirety.

The present invention relates to the field of microbiology. More precisely, the invention relates to the detection of at least one mechanism of resistance to carbapenems of at least one microorganism from a sample by using mass spectrometry.

Since Pasteur's discovery of microbes, microorganisms have been studied by microscopy and biochemical analyses. These conventional methods are often long and tedious, and analytical alternatives were sought very early on. This is why the analysis of bacteria by mass spectrometry was initiated from 1975 by J. Anhalt and C. Fenselau [1].

This preliminary work was followed by the study of fatty acids from the wall of the microorganisms using gas chromatography combined with mass spectrometry (GC-MS) [2]. This method was popularised under the English term FAME, standing for Fatty Acid Methyl Ester. It currently constitutes a reference method for taxonomic studies. However, its use remains limited to certain specialised laboratories dealing with the treatment of the sample by saponification, hydrolysis and derivation.

In 1996, the works by M. Claydon et al. [3] as well as by T. Krishnamurthy and P. Ross [4] demonstrated the possibility of identifying different bacterial species with a MALDI-TOF mass spectrometer (English acronym for Matrix Assisted Laser Desorption Ionization-Time Of Flight). The analysis combines the acquisition of a mass spectrum and the interpretation of expert software. It is extremely simple and can be carried out in a few minutes. However it has only been making it into medical analysis laboratories fairly recently [5]. Its clinical use is currently limited to the identification of bacteria and yeast species. It is not routinely used to identify resistances to antimicrobials.

Yet the identification of resistances to antimicrobials such as antibiotics is an essential element in ensuring optimal patient care.

Other mass spectrometry methods, particularly in tandem, have been proposed to meet these needs. By way of example, it is possible to cite the work of C. Fenselau et al. for identifying β-Lactamase with a quadripole-TOF (Q-TOF) [6].

However these research results are not applicable to routine clinical use. They were obtained with research instruments requiring highly qualified personnel. The analysis times, often greater than one hour per sample, are incompatible with the workload of a microbiological analysis laboratory.

More recently, S. Hofstadler et al. [7] proposed a method combining a microbial genome amplification by PCR to a detection of the PCR products by electrospray-TOF (ESI-TOF). This method is now fully automated [8]. However, it requires a PCR amplification with the flaws inherent in molecular biology, namely extraction yield, cost of the probes, etc.

In this context, the objective of the present invention is to propose a method of detecting mechanisms of resistance to carbapenems which makes it possible to overcome the disadvantages of the prior art methods, namely providing an inexpensive method, without reagents specific to each species, particularly compared to molecular biology methods, which gives a result in a short amount of time, less than one hour, and which can be used in routine clinical work, without requiring highly qualified personnel.

To this end, the invention proposes a new method of detecting, by mass spectrometry, at least one mechanism of resistance to at least one antimicrobial of at least one microorganism from a sample, characterised in that the antimicrobial is a carbapenem and in that proteins and/or peptides are detected as markers of said mechanism of resistance to at least one carbapenem-class antibiotic.

Preferably, the resistance markers are proteins from said at least one microorganism. Advantageously, markers of resistance to several different antimicrobials can be detected simultaneously.

As indicated in application PCT/FR2010/052181, markers of type and/or virulence of said microorganisms can be detected in the same way by mass spectrometry prior to or at the same time as the detection of the resistance mechanism markers.

Markers of resistance to at least one carbapenem-class antimicrobial is understood to mean molecules of protein origin which are characteristic of said properties.

Carbapenems are antibiotics belonging to the beta-lactam family and their main representatives are imipenem, meropenem, ertapenem and doripenem. These molecules are broken down by the beta-lactamases 2df, 2f and 3a of the classification by Bush and Jacoby ([9], Antimicrobial Agents and Chemotherapy, 2010; 54 (3): 969-976).

Determination of the resistance to at least one antimicrobial is understood to mean determining the susceptibility of a microorganism to being destroyed by an antimicrobial. The proteins involved in the resistance mechanisms will differ depending on the family and the species.

The nomenclature of the beta-lactamases, beta-lactam-resistant bacterial enzymes, is not standardised. They are either classified in four molecular classes (A to D) on the basis of their primary structure, or in functional groups on the basis of the target substrates and their resistance to inhibitors (for an overview, see [9] Bush and Jacoby, supra). For molecular classification, sequencing techniques have made more precise classification possible: for example, 183 variants of the TEM protein have been described (labelled TEM-i, with i being between 1 and 183). For the functional classification, Bush and Jacoby (supra) have proposed new functional subgroups:

-   -   the group 1 enzymes are cephalosporinases belonging to the         molecular class C. CMY and FOX are plasmid-borne enzymes,         belonging to this subgroup.     -   the group 2 enzymes belong to molecular classes A and D. This         group is itself subdivided into subgroups, 2b, 2be, 2br, 2ber,         2d, 2de, 2df, 2f, etc. CTX-M (2be) and TEM (including 2be, 2br)         are enzymes belonging to this subgroup. The subgroup 2b         corresponds to broad-spectrum beta-lactamases which are         inhibited by clavulanic acid, sulfobactam, or tazobactam. The         subgroup 2be corresponds to extended-spectrum beta-lactamases         (ESBL), which are also inhibited by clavulanic acid, sulfobactam         or tazobactam. The subgroup 2br corresponds to beta-lactamases         from the subgroup 2b which are insensitive to inhibition by         clavulanic acid, sulfobactam or tazobactam. The subgroup 2df         includes OXAs having a spectrum extended to carbapenems. Group         2f corresponds to carbapenemase beta-lactamases such as KPC.     -   group 3 encompasses the metallo-beta-lactamases which hydrolyse         carbapenems, such as IMP, VIM, SPM, GIM, SIM, AIM, KHM, DIM or         NDM.

NDM-1 beta-lactamase was described in 2010 (Kumarasamy et al., 2010, Lancet Infect. Dis., 10:597-602). It corresponds to a metallo-beta-lactamase which confers a resistance to all beta-lactams except aztreonam.

KPC beta-lactamases were described from 2001 in the United States (Yigit et al., 2001, Antimicrobio. Agents Chemother., 45:1151-1161) and then throughout the world. They correspond to class-A beta-lactamases which confer a resistance to cephalosporins and to carbapenems, in particular to imipenem and to meropenem. IMP beta-lactamases were described from 1994 in Japan (Osano et al., 1994, Antimicrobio. Agents Chemother., 38:71-78) and then throughout the world. They correspond to metallo-beta-lactamases which confer a resistance to cephalosporins and to carbapenems, but which do not confer resistance to Temocillin and to aztreonam.

VIM beta-lactamases were described from 1999 in Europe (Lauretti et al., 1999, Antimicrobio. Agents Chemother., 43:1584-1590) and then throughout the world. They correspond to metallo-beta-lactamases which confer a resistance to cephalosporins and to carbapenems, but which do not confer resistance to aztreonam.

The first GES beta-lactamase was isolated in 1998 in French Guiana (Poirel et al., 2000, Antimicrobio. Agents Chemother., 43:622-632). This enzyme (GES-1) conferred an ESBL resistance. The second isolate from a bacterium bearing a GES beta-lactamase was achieved in 2000 in South Africa (Poirel et al., 2001, Antimicrobio. Agents Chemother., 45:2598-2603). This enzyme (GES-2) conferred a resistance to cephalosporins and to carbapenems such as imipenem.

IND beta-lactamases were described for the first time in 1999 (Bellais et al., 1999, FEMS Microbio. Lett., 171:127-132). They correspond to metallo-beta-lactamases which confer a resistance to cephalosporins and to carbapenems.

SME beta-lactamases were described for the first time in 1994 (Naas et al., 1994, Antimicrobio. Agents Chemother., 38:1262-1270). They correspond to class-A beta-lactamases which confer a resistance to cephalosporins and to carbapenems.

OXA beta-lactamases (or oxacillinases) correspond to Class-D beta-lactamases. According to their primary sequence, they can confer resistances to cephalosporins or to cephalosporins and to carbapenems (Poirel et al., 2010, Antimicrobio. Agents Chemother., 54:24-38).

The method of the invention can be employed to detect mechanisms of resistance to carbapenems in bacteria. Thus, for example, as bacteria in which it is possible to seek a mechanism of resistance to carbapenems according to the method of the invention, non-exhaustive mention may be made of: Escherichia coli, Klebsiella pneumoniae, Pseudomonas aeruginosa, Acinetobacter baumannii, Bacillus spp, Stenotrophomonas maltophilia, Aeromonas spp, Bacteroides fragilis, Pseudomonas otitidis and Enterobacter cloacae, and more generally, the Enterobacteriaceae, which carry the bla_(NDM-1) or bla_(KPC) resistance gene. It should further be noted that the strains known to be resistant to carbapenems are also resistant to cephalosporins and to penicillins.

Thus, the method according to the invention also makes it possible to detect a mechanism of resistance to said antibiotics.

The sample on which the method of the invention can be employed is any sample susceptible of containing a target microorganism. The sample can be of biological origin, either animal, vegetable or human. In this case it may correspond to a specimen of biological fluid (whole blood, serum, plasma, urine, cerebrospinal fluid, organic secretion, for example), a tissue specimen or isolated cells. This specimen can be used such as it is, insofar as the markers of mechanisms of bacterial resistance to beta-lactams are available in the sample tested, or it can, prior to the analysis, undergo preparation by enrichment, extraction, concentration, purification, culturing, in accordance with methods known to the person skilled in the art.

The sample can be of industrial origin, or, according to a non-exhaustive list, can be an air specimen, a water specimen, a surface specimen, a part or a manufactured product, or a food product. Amongst the food samples, non-exhaustive mention can be made of a sample of a dairy product (yogurts, cheeses), of meat, of fish, of egg, of fruit, of vegetable, of water, of a beverage (milk, fruit juice, soda, etc.). These food samples can also come from sauces or ready meals. Finally, a food sample can come from an animal feed, such as animal meals.

Upstream of the detection by mass spectrometry, the sample to be analysed is preferably pretreated to produce peptides from the entirety of the proteins present in the sample to fragment these proteins into peptides, for example by digestion with a proteolytic enzyme (protease), or by the action of a chemical reagent. In fact, the cleaving of the protein can be performed by a physico-chemical treatment, by a biological treatment or by a combination of the two treatments. Amongst the useable treatments, mention can be made of treatment by hydroxyl radicals, in particular with H₂O₂. Treatment by hydroxyl radicals results in a cutting of the peptide bonds which takes place randomly on any of the protein's peptide bonds. The hydroxyl radical concentration determines the number of cleavages performed, and therefore the length of the peptide fragments obtained. Other chemical treatments can also be used such as, for example, cyanogen bromide (CNBr) treatment which specifically splits the peptide bonds at the carboxyl group of the methionyl residues. It is also possible to perform partial acid cleaving at the aspartyl residues by heating a solution of proteins in trifluoroacetic acid to 1000° C.

Treatment of the proteins by enzymatic digestion is nevertheless preferred over physico-chemical treatment because it preserves more of the structure of the protein, and is easier to control. “Enzymatic digestion” is understood to mean the single or combined action of one or more enzymes under appropriate reaction conditions. The enzymes carrying out the proteolysis, which are called proteases, cut the proteins at specific locations. Each protease generally recognises a sequence of amino acids within which it always makes the same cut. Certain proteases recognise a single amino acid or a sequence of two amino acids between which they perform a cleavage, whereas other proteases only recognise longer sequences. These proteases can be endoproteases or exoproteases. Amongst the known proteases, mention may be made of the following as described in WO2005/098071:

-   -   specific enzymes such as trypsin which splits the peptide bond         at the carboxyl group of the Arg and Lys residues, endolysin         which cleaves the peptide bond of the —CO group of the lysines,         chymotrypsin which hydrolyses the peptide bond at the carboxylic         group of the aromatic residues (Phe, Tyr and Tip), pepsin which         makes a cut at the NH₂ group of the aromatic residues (Phe, Tyr         and Trp), the protease V8 from the V8 strain of Staphylococcus         aureus which cleaves the peptide bond at the carboxylic group of         the Glu residue;     -   the non-specific enzymes such as thermolysin from the bacteria         Bacillus thermoproteolyticus which hydrolyses the peptide bond         of the NH₂ group of hydrophobic amino acids (Xaa-The, Xaa-Ile,         Xaa-Phe), subtilisin and pronase which are bacterial proteases         which hydrolyse practically all the bonds and can transform the         proteins into oligopeptides under controlled reaction conditions         (enzyme concentration and duration of reaction).

Several proteases may be used simultaneously, if their modes of action are compatible, or they may be used successively. Within the framework of the invention, the digestion of the sample is preferably performed by the action of a protease enzyme, for example trypsin.

The generation of peptides using a chemical reagent or a protease can be obtained by means of a simple reaction in solution. It can also be performed with a microwave oven [10], or under pressure [11], or even with an ultrasound device [12]. In these three latter cases, the protocol will be much faster.

Amongst the peptides thus obtained, the peptides specific to the protein are referred to as proteotypic peptides. It is these which will be assayed by mass spectrometry. According to the invention, the markers of the mechanisms of bacterial resistance to carbapenems are proteins from the bacterium in which the mechanisms of resistance to cephalosporins are to be sought. In particular, said proteins are digested into peptides, preferably by an enzyme, and more preferably by trypsin.

Similarly, the sample containing protein markers characterising mechanisms of bacterial resistance to carbapenems can also be pretreated for the purposes of purification. This purification pretreatment can be employed before or after the peptide production step as described above.

The sample purification pretreatment is widely known to the person skilled in the art and may in particular employ the techniques of centrifugation, filtration, electrophoresis or chromatography. These separating techniques can be used alone or in combination with one another to obtain a multidimensional separation. For example, multidimensional chromatography can be used by combining separation by ion exchange chromatography with reversed-phase chromatography, as described by T. Fortin et al. [13], or H. Keshishian et al. [14]. In these publications, the chromatography medium can be in a column or in a cartridge (solid-phase extraction).

The electrophoretic or chromatographic fraction (or the retention time in monodimensional or multidimensional chromatography) of the proteotypic peptides is characteristic of each peptide, and employing these techniques therefore makes it possible to select the proteotypic peptide or peptides to be assayed. Such a fractionation of the produced peptides makes it possible to increase the specificity of the subsequent assay by mass spectrometry.

An alternative to the electrophoresis or chromatography techniques for the fractionation of the peptides consists in specifically purifying the N-glycopeptides ([15] and patent application WO 2008/066629). However, such a purification only makes it possible to quantify the peptides which have undergone an N-glycosylation post-translational modification. Not all proteins are glycosylated though, which therefore limits its use.

The mass spectrometry to be employed in the method of the invention is widely known to the person skilled in the art as a powerful tool for analysing and detecting different types of molecules. Generally, any type of molecule able to be ionised can be detected according to its molecular mass with the aid of a mass spectrometer. According to the nature of the molecule to be detected, whether of protein or metabolic origin, certain mass spectrometry technologies can be more suitable. Nevertheless, whatever mass spectrometry method is used for the detection, this latter includes a step of ionising the target molecule into so-called molecular ions, in the present case a step of ionising the characterising markers, and a step of separating the molecular ions obtained according to their mass.

All mass spectrometers therefore comprise:

-   -   an ionising source intended to ionise the markers present in the         sample to be analysed, i.e. to confer a positive or negative         charge upon these markers;     -   a mass analyser intended to separate the ionised markers, or         molecular ions, according to their mass-to-charge ratio (m/z);     -   a detector intended to measure the signal produced either         directly by the molecular ions, or by ions produced from         molecular ions as detailed hereafter.

The ionisation step necessary for employing mass spectrometry can be performed via any method known to the person skilled in the art. The ionising source makes it possible to transform the molecules to be assayed into a gaseous and ionised state. An ionising source can be used either in positive mode to study the positive ions, or in negative mode to study the negative ions. Several types of sources exist and will be used depending on the result sought and the molecules analysed. In particular, mention may be made of:

-   -   electron ionisation (EI), chemical ionisation (CI) and         desorption chemical ionisation (DCI)     -   fast atom bombardment (FAB), metastable atom bombardment (MAB)         or ion bombardment (SIMS, LSIMS)         http://fr.wikipedia.org/wiki/Spectrom%C3%A9trie_de_masse_%C3%A0_ionisation_secondaire     -   inductively coupled plasma (ICP)         http://fr.wikipedia.org/wiki/Torche_%C3%A0_plasma_(chimie)     -   atmospheric-pressure chemical ionisation (APCI) and         atmospheric-pressure photoionisation (APPI)         http://fr.wikipedia.org/wiki/Ionisation_chimique_%C3%A0_pression_atmosph%C3%A9rique     -   electronebulisation or electrospray (ESI)         http://fr.wikipedia.org/wiki/Ionisation_par_%C3%A9lectron%C3%A9buliseur_(ESI)     -   matrix-assisted laser desorption/ionisation (MALDI),         surface-activated laser desorption/ionisation (SELDI) or         desorption/ionisation on silicon (DIOS)         http://fr.wikipedia.org/wiki/D%C3%A9sorption-ionisation_laser_assist%C3%A9e_par_matrice     -   ionisation/desorption by interaction with metastable species         (DART)

In particular, ionisation can be employed as follows: the sample containing the target molecules is introduced into an ionisation source, where the molecules are ionised in gaseous state and thus transformed into molecular ions which correspond to the initial molecules. An electrospray ionisation (ESI) source makes it possible to ionise a molecule by making it pass from a liquid state into a gaseous state. The molecular ions obtained therefore correspond to the molecules present in liquid state, with, in positive mode, one, two, or even three or more additional protons and therefore carry one, two, or even three or more charges. For example, when the target molecule is a protein, an ionisation of the proteotypic peptides obtained after fractionation of the target protein, by means of an electrospray source functioning in positive mode, leads to polypeptide ions in gaseous state, with one, two, or even three or more additional protons and which therefore carry one, two, or even three or more charges, and makes it possible to move from a liquid state to a gaseous state [16]. This type of source is particularly well suited when the target molecules or proteotypic peptides obtained are separated beforehand by reversed-phase liquid chromatography. Nevertheless, the ionisation yield of the molecules present in the sample may vary depending on the concentration and the nature of the different species present. This phenomenon leads to a matrix effect well known to the person skilled in the art.

A MALDI ionisation source will allow ionisation of the molecules from a solid-state sample.

The mass analyser in which the step of separating the ionised markers according to their mass-to-charge ratio (m/z) is performed is any mass analyser known to the person skilled in the art. Mention can be made of low-resolution analysers, quadripole or quadrupole (Q), 3D ion trap (IT) or linear ion trap (LIT), also called ion trap, and high-resolution analysers which make it possible to measure the exact mass of the analytes and which in particular use the magnetic sector linked to an electric sector, the time of flight (TOF), Fourier transform ion cyclotron resonance (FT-ICR), orbitrap.

The separation of the molecular ions depending upon their m/z ratio can be employed just once (single mass spectrometry or MS), or several successive MS separations can be conducted. When two successive MS separations are carried out, the analysis is called MS/MS or MS². When three successive MS separations are carried out, the analysis is called MS/MS/MS or MS³, and more generally, when n successive MS separations are carried out, the analysis is called MS^(n).

Amongst the techniques which employ several successive separations, SRM (Selected Reaction Monitoring) mode when detecting or assaying a single target molecule, or MRM (Multiple Reaction Monitoring) mode when detecting or assaying several target molecules are particular uses of MS² separation. Similarly the MRM³ mode is a particular use of MS/MS/MS separation. This is referred to as targeted mass spectrometry.

In the case of a detection in single MS mode, it is the mass-to-charge ratio of the molecular ions obtained which is correlated to the target molecule to be detected.

In the case of detection in MS/MS mode, essentially two steps are added, compared to an MS assay, which are:

-   -   a fragmentation of the molecular ions, then called precursor         ions, to give ions called 1^(st) generation fragment ions, and     -   a separation of the ions called 1^(st) generation fragment ions         according to their mass (m/z)₂, the ratio (m/z)₁ corresponding         to the ratio (m/z) of the precursor ions.

It is therefore the mass-to-charge ratio of the 1^(st) generation fragment ions thus obtained which is correlated to the target molecule to be detected. First-generation fragment ion is understood to be an ion derived from the precursor ion, following a fragmentation step and of which the mass-to-charge ratio m/z is different from the precursor ion.

The (m/z)₁ and (m/z)₂ pairs are called transitions and are representative of the characteristic ions to be detected.

The choice of the characteristic ions which are detected to be correlated to the target molecule is made by the person skilled in the art in accordance with the standard methods. Their selection will advantageously lead to the most sensitive, specific and robust assays possible, in terms of reproducibility and reliability. In the methods developed for the selection of proteotypic peptides (m/z)₁, and of the first-generation fragment (m/z)₂, the choice is essentially based on the intensity of the response. For more details, it is possible to refer to V. Fusaro et al. [17]. Commercially available software, such as the MIDAS and MRM Pilot software from Applied Biosystems or MRMaid [18] can be used by the person skilled in the art to allow him to predict all the possible transition pairs. He can also make use of a database called PeptideAtlas constructed by F Desiere et al. [19] to compile all of the MRM transitions of peptides described by the scientific community. This database PeptideAtlas is freely available on the internet. For non-protein molecules, it is also possible to use databases, such as, for example, the one accessible through the Cliquid software from the company Applied Biosystems (United States of America).

An alternative approach to selecting the proteotypic peptides (m/z)₁ and (m/z)₂ consists in using MS/MS fragmentation spectra obtained during other work. This work can be, for example, the phases of biomarker discovery and identification by proteomic analysis. This approach was proposed by Thermo Scientific during user conferences [18]. It makes it possible to generate a list of candidate transitions from the peptides identified through testing by the SIEVE (Thermo Scientific) software. Certain criteria were detailed by J. Mead et al. [18] for the choice of the ions (m/z)₁ and (m/z)₂ and are detailed hereafter:

-   -   peptides with internal cleavage sites, i.e. with internal Lysine         or Arginine, must be avoided, unless the Lysine or Arginine is         followed by Proline,     -   peptides with Aspargine or Glutamine must be avoided because         they may deaminate,     -   peptides with Glutamine or Glutamic Acid at the N-terminal must         be avoided because they may cyclise spontaneously,     -   peptides with Methionine must be avoided because they may be         oxidised,     -   peptides with Cysteine must be avoided because they may be         non-reproducibly modified during a potential step of         denaturation, reduction and blocking of the thiol functions,     -   peptides with Proline may be considered to be favourable because         they generally produce intense fragments in MS/MS with a very         strong single peak. However, a very strong single fragment does         not make it possible to validate the identity of the transition         in a complex mixture. Indeed, only the simultaneous presence of         several characteristic fragments makes it possible to verify         that the precursor ion sought has actually been detected,     -   the peptides having a Proline adjacent to the C-terminal         (Position n-1) or in second position relative to the C-terminal         (position n-2) should be avoided because, in this case, the size         of the first-generation peptide fragment is generally considered         to be too small to be sufficiently specific,     -   the selection of fragments having a mass greater than the         precursor should be given preference in order to promote         specificity. To this end, it is necessary to select a dicharged         precursor ion and select the most intense first-generation ion         fragment having a mass greater than the precursor, i.e. a         monocharged first-generation fragment ion.

The fragmentation of the selected precursor ions is performed in a fragmentation cell such as the triple quadripole model [20], ion trap model [21], or time-of-flight (TOE) model [22], which also make it possible to separate ions. The fragmentation or fragmentations will be conventionally performed by collision with an inert gas such as argon or nitrogen, within an electrical field, by photo-excitation or photo-dissociation using an intense light source, collision with electrons or radical species, by applying a potential difference, for example in a time-of-flight tube, or by any other activation mode. The characteristics of the electrical field determine the intensity and nature of the fragmentation. Thus, the electrical field applied in the presence of an inert gas, for example in a quadripole, determines the collision energy provided to the ions. This collision energy will be optimised, by the person skilled in the art, to increase the sensitivity of the transition to be assayed. By way of example, it is possible to vary the collision energy between 5 and 180 eV in q2 in an AB SCIEX QTRAP® 5500 mass spectrometer from the company Applied Biosystems (Foster City, United States of America). Similarly, the duration of the collision step and the excitation energy within, for example, an ion trap will be optimised by the person skilled in the art to lead to the most sensitive assay. By way of example, it is possible to vary this duration, called excitation time, between 0.010 et 50 ms and the excitation energy between 0 and 1 (arbitrary unit) in Q3 in an AB SCIEX QTRAP® 5500 mass spectrometer by the company Applied Biosystems.

Finally, the detection of the selected characteristic ions takes place in the conventional manner, particularly by means of a detector and a processing system. The detector collects the ions and produces an electrical signal whose intensity depends on the amount of ions collected. The signal obtained is then amplified such that it can be processed by computer. A computer data processing assembly makes it possible to transform the information received by the mass spectrum detector.

The principle of the SRM mode, or even of the MRM mode, is to specifically select a precursor ion, fragment it, and then specifically select one of its fragment ions. For such applications, triple quadripole or hybrid triple quadripole/ion trap devices are generally used.

In the case of a triple quadripole device (Q1q2Q3) used in MS² mode, with a view to assaying or detecting a target protein, the first quadripole (Q1) makes it possible to filter the molecular ions corresponding to the proteotypic peptides characteristic of the protein to be assayed and obtained during an earlier digestion step, depending on their mass-to-charge ratio (m/z). Only the peptides having the mass-to-charge ratio of the proteotypic peptide sought, which ratio is called (m/z)₁, are transmitted into the second quadripole (q2) and act as precursor ions for the subsequent fragmentation. The analyser q2 can fragment the peptides of mass-to-charge ratio (m/z)₁ into first-generation fragment ions. Fragmentation is generally obtained through collision of the precursor peptides with an inert gas, such as nitrogen or argon in q2. The first-generation fragment ions are transmitted into a third quadripole (Q3) which filters the first-generation fragment ions depending on a specific mass-to-charge ratio, called (m/z)₂. Only the first-generation fragment ions having the mass-to-charge ratio of a fragment characteristic of the sought proteotypic peptide (m/z)₂ are transmitted into the detector in order to be detected, or even quantified.

This mode of operation exhibits a double selectivity, with regard to the selection of the precursor ion on the one hand, and the selection of the first-generation fragment ion on the other hand. Mass spectrometry in SRM or MRM mode is therefore advantageous for quantification.

When the mass spectrometry employed in the method according to invention is tandem mass spectrometry (MS², MS³, MS⁴ or MS⁵), several mass analysers can be linked to one another. For example, a first analyser separates the ions, a collision cell makes it possible to fragment the ions, and a second analyser separates the fragment ions. Certain analysers, such as the ion traps or the FT-ICR, constitute several analysers in one and make it possible to fragment the ions and analyse the fragments directly.

According to preferred embodiments of the invention, the method of the invention comprises one or more of the following characteristics:

-   -   the mass spectrometry employed for the properties of potential         resistance to at least one antimicrobial is MS/MS spectrometry,         which has the advantage of producing a fragment which is         specific to the molecule to be detected or quantified, and thus         of providing great specificity to the assaying method;     -   the MS/MS spectrometry is MRM which has the advantage of using         an analysis cycle time in the mass spectrometer of several tens         of milliseconds, which makes it possible to detect or quantify,         with a high degree of sensitivity, a large number of different         molecules in a multiplexed manner;     -   where applicable, the determination of the type properties and         of the virulence factor is performed in the same mass         spectrometry apparatus as the determination of the markers of         resistance to at least one antimicrobial, preferably         simultaneously, which has the advantage of reducing the analysis         time and the cost of the instrument, which also facilitates the         processing and the yielding of the results.

In addition to determining the resistance to an antibiotic, it is necessary to identify the microorganism or microorganisms present in the sample to be tested.

The methods of identifying microorganisms are widely known to the person skilled in the art, as described for example by Murray P. R. et al. in Manual of Clinical Microbiology, 2007, 9^(th) edition, and especially in Vol. I, Section III, chapters 15 and 16 for bacteria and yeasts, Vol. II, Section VI, chapter 82 for viruses, and Vol. II, Section X, chapter 135 for protozoa. As an example of conventional identification methods, mention can be made of the determination of the biological profile, by using the Vitek 2 (bioMérieux) identification cards, for example, or even by using molecular biology techniques with identification criteria based on the study of the presence of certain genes, and on the study of their sequence.

Identification can be performed directly from the sample in which the identification is made, or the microorganisms contained in the sample can be cultured using methods well known to the person skilled in the art with optimal culture media and culturing conditions tailored to the species of microorganisms to be sought, as described by Murray P. R. et al. in Manual of Clinical Microbiology, 2007, 9^(th) edition, Vol. I, Section III, chapter 14, and in particular in Vol. I, Section IV, chapter 21 for bacteria, and Vol. II, Section VI, chapter 81 for viruses, Vol. II, Section VIII, chapter 117 for yeasts, and Vol. II, Section X, chapter 134 for protozoa.

Thus, generally, in the case of an identification using a biochemical method of a bacterium in a specimen, it is first necessary to obtain it in a pure culture, for example after seeding on agar. Molecular biology (PCR) can in certain cases be applied directly to the sample to be analysed.

Instead of cultivating the microorganisms, they can be concentrated by capture directly in the sample by means of active surfaces. Such a method was described by W.-J. Chen et al. [10] who captured different bacterial species with the aid of magnetic beads with an Fe₃O₄/TiO₂-activated surface. Capture by other means is also possible, such as a capture by lectins [23], or by antibodies [24], or by Vancomycin [25]. The capture makes it possible to concentrate the microorganisms and thus to reduce or even eliminate the culture step. This results in a considerable time saving.

The identification may also be performed by mass spectrometry, in accordance with the techniques described previously, preferably by MS, by MS/MS, or even by MS followed by MS/MS spectrometry, which constitutes one embodiment of the invention. In this case too, the sample can be subjected to a culture step beforehand, such as seeding on agar.

The use of an MS identification method is advantageous in that it may be carried out in a few minutes, and in that it requires a mass spectrometer with a single analyser, i.e. a less complex instrument than a tandem mass spectrometer used in MS/MS.

The use of a method of identification by MS followed by MS/MS spectrometry is also advantageous. It makes it possible to check the identity of the ions observed by MS, which increases the specificity of the analysis.

The use of an MRM-type MS/MS identification method has the advantage of being more sensitive and simpler than the conventional MS followed by MS/MS approaches. This method requires neither a high-performance software to process the information between the acquisition of the MS spectrum and of the MS/MS spectrum, nor a change in the setting of the machine parameters for linking up MS then MS/MS spectra.

The method of identification by MS may be employed with an electrospray source on a raw sample, as described by S. Vaidyanathan et al. [26] or by R. Everley et al. [27] after chromatographic separation. Different m/z ranges thus make it possible to identify the microorganisms. S. Vaidyanathan et al. used a window of between 200 and 2000 Th, and R. Everley et al. used a window of between 620 and 2450 Th. The mass spectra may also be deconvoluted to access the mass of the proteins independently of their charge state. R. Everley et al. therefore used masses of between about 5,000 and 50,000 Da. Alternatively, the method of identification by MS can also be employed with the aid of a MALDI-TOF, as described by Claydon et al. [3] and T. Krishnamurthy and P. Ross [4]. The analysis combines acquisition of a mass spectrum and interpretation of expert software. It is extremely simple and can be carried out in a few minutes. This method of identification is currently becoming more widespread in medical analysis laboratories [28].

The identification of bacteria by MS followed by MS/MS via their proteins present in the sample has been applied widely by a number of teams. By way of example, mention can be made of the recent work of Manes N. et al. [29], who studied the peptidome of Salmonella enterica, or the work of R. Nandakumar et al. [30] or of L. Hernychova et al. [31] who have studied the proteome of bacteria after digestion of the proteins with trypsin. The conventional approach consists in i) acquiring an MS spectrum, ii) successively selecting each precursor ion observed on the MS spectrum with an intense signal, iii) successively fragmenting each precursor ion and acquiring its MS/MS spectrum, iv) interrogating protein databases such as SWISS-PROT or NCBI, through software such as Mascot (Matrix Science, London, United Kingdom) or SEQUEST (Thermo Scientific, Waltham, United States of America), to identify the peptide which has a strong probability of matching the MS/MS spectrum observed. This method may lead to the identification of a microorganism if a protein or a peptide characteristic of the species is identified.

One of the advantages of the use of mass spectrometry lies in that it is particularly useful for quantifying molecules, in the present case the markers of the mechanisms of bacterial resistance to beta-lactams. To this end, the current intensity detected is used, which is proportional to the quantity of target molecule. The current intensity thus measured may serve as a quantitative measurement making it possible to determine the quantity of target molecule present, which is characterised by its expression in International System (SI) mol/m³ or kg/m³ units, or by multiples or sub-multiples of these units, or by the usual derivatives of the SI units, including multiples or sub-multiples thereof. As a non-limiting example, the units such as ng/ml or fmol/l are units characterising a quantitative measurement.

A calibration is nevertheless necessary in order to be able to correlate the measured area of the peak, which corresponds to the current intensity induced by the detected ions, to the quantity of target molecule to be assayed. For this purpose, the calibrations conventionally used in mass spectrometry may be employed, within the framework of the invention. MRM assays are conventionally calibrated with the aid of external standards or, preferably, with the aid of internal standards such as described by T. Fortin et al. [13]. If the target molecule is a proteotypic peptide which permits the assaying of a protein of interest, the correlation between the quantitative measurement and the quantity of target proteotypic peptide, and subsequently of protein of interest, is obtained by calibrating the measured signal relative to a standard signal for which the quantity to be assayed is known. The calibration may be performed using a calibration curve, for example obtained by successive injections of standard proteotypic peptide at different concentrations (external calibration), or preferably by internal calibration using a heavy peptide as an internal standard, for example in accordance with the AQUA, QconCAT or PSAQ methods detailed below. “Heavy peptide” is understood to mean a peptide corresponding to the proteotypic peptide, but in which one or more atoms of carbon 12 (¹²C) is (are) replaced by carbon 13 (¹³C), and/or one or more atoms of nitrogen 14 (¹⁴N) is (are) replaced by nitrogen 15 (¹⁵N).

The use of heavy peptides as internal standards (AQUA) was also proposed in US patent application 2004/0229283. The principle is to artificially synthesise proteotypic peptides with amino acids containing isotopes which are heavier than the usual natural isotopes. Such amino acids are obtained, for example, by replacing some of the atoms of carbon 12 (¹²C) with carbon 13 (¹³C), or by replacing some of the atoms of nitrogen 14 (¹⁴N) with nitrogen 15 (¹⁵N). The artificial peptide (AQUA) thus synthesised has strictly the same physicochemical properties as the natural peptide (with the exception of a higher mass). It is generally added, at a given concentration, to the sample, upstream of assaying by mass spectroscopy, for example between the treatment entailing the cleaving of the proteins in the sample of interest and the fractionation of the peptides obtained after the treatment step. Thus, the AQUA peptide is co-purified with the natural peptide to be assayed, during fractionation of the peptides. The two peptides are therefore injected simultaneously into the mass spectrometer, for assaying. They then undergo the same ionisation yield in the source. The comparison of the peak areas of the natural and AQUA peptides, whose concentration is known, makes it possible to calculate the concentration of the natural peptide and thus the concentration of the protein to be assayed. A variation of the AQUA technique was proposed by J.-M. Pratt et al. [32] under the name QconCat. This variant is also described in patent application WO 2006/128492. It consists in concatenating various AQUA peptides and producing the artificial polypeptide in the form of a heavy recombinant protein. The recombinant protein is synthesised with amino acids comprising heavy isotopes. In this way, it is possible to obtain a standard to calibrate the simultaneous assay of several proteins at lower cost. The QconCAT standard is added from the start, upstream of the treatment entailing the cleaving of the proteins and prior to the steps of protein fractionation, denaturation, reduction and blocking of the protein thiol functions, if these are present. The QconCAT standard therefore undergoes the same treatment cycle entailing the cleaving of the proteins as the natural protein, which makes it possible to take account of the yield from the treatment step which entails the cleaving of the proteins. In fact, the treatment, particularly by digestion, of the natural protein may not be complete. In this case, the use of an AQUA standard would lead to underestimating the quantity of natural protein. For full assaying, it may therefore be important to take into account the yields from treatment which entails the cleaving of the proteins. However, V. Brun et al. [33] have shown that the QconQAT standards sometimes do not exactly reproduce the treatment yield particularly by digestion of the natural protein, undoubtedly due to a three-dimensional conformation different from the QconCAT protein.

V. Brun et al. [33] then proposed the use of a method dubbed PSAQ, and described in patent application WO 2008/145763. In this case, the internal standard is a recombinant protein having the same sequence as the natural protein but synthesised with heavy amino acids. The synthesis is performed ex-vivo with heavy amino acids. This standard has strictly the same physicochemical properties as the natural protein (with the exception of a higher mass). It is added from the start, before the protein fractionation step, when the latter is present. It is therefore co-purified with the native protein, during the protein fractionation step. It exhibits the same treatment yield, particularly by digestion, as the native protein. The heavy peptide obtained after cleaving is also co-purified with the natural peptide, if a peptide fractionation step is performed. The two peptides are therefore injected simultaneously into the mass spectrometer, to be quantitatively assayed. They then undergo the same ionisation yields in the source. Comparison of the peak areas of the natural and the reference peptides in the PSAQ method makes it possible to calculate the concentration of the protein to be assayed taking into account all of the steps of the assay method.

All of these techniques, namely AQUA, QconCAT or PSAQ or any other calibration technique, used in the mass spectrometry assays and in particular in MRM or MS assays, may be employed to carry out calibration, within the framework of the invention.

Preferably, the mass spectrometry used in the detection method according to the invention is MS/MS. More preferably, the mass spectrometry is MRM.

The method of the invention makes it possible to detect resistances to carbapenems, characterised by the detection of at least one peptide as a resistance marker. Said resistance marker peptide preferably belongs to the proteins NDM, KPC, GES, IMP, IND, SME, VIM or OXA.

In particular, the detection of a mechanism of resistance to carbapenems induced by the expression of an NDM protein is characterised by the detection of at least one peptide belonging to an NDM protein and its different sequence variants SEQ ID No. 1 and SEQ ID No. 1078 to SEQ ID No. 1080.

SEQ ID No. 1: MELPNIMHPVAKLSTALAAALMLSGCMPGEIRPTIGQQMETGDQRFGDLV FRQLAPNVWQHTSYLDMPGFGAVASNGLIVRDGGRVLVVDTAWTDDQTAQ ILNWIKQEINLPVALAVVTHAHQDKMGGMDALHAAGIATYANALSNQLAP QEGMVAAQHSLTFAANGWVEPATAPNFGPLKVFYPGPGHTSDNITVGIDG TDIAFGGCLIKDSKAKSLGNLGDADTEHYAASARAFGAAFPKASMIVMSH SAPDSRAAITHTARMADKLR SEQ ID No. 1078 MELPNIMHPVAKLSTALAAALMLSGCMAGEIRPTIGQQMETGDQRFGDLV FRQLAPNVWQHTSYLDMPGFGAVASNGLIVRDGGRVLVVDTAWTDDQTAQ ILNWIKQEINLPVALAVVTHAHQDKMGGMDALHAAGIATYANALSNQLAP QEGMVAAQHSLTFAANGWVEPATAPNFGPLKVFYPGPGHTSDNITVGIDG TDIAFGGCLIKDSKAKSLGNLGDADTEHYAASARAFGAAFPKASMIVMSH SAPDSRAAITHTARMADKLR SEQ ID No. 1079 MELPNIMHPVAKLSTALAAALMLSGCMPGEIRPTIGQQMETGDQRFGDLV FRQLAPNVWQHTSYLDMPGFGAVASNGLIVRDGGRVLLVDTAWTDDQTAQ ILNWIKQEINLPVALAVVTHAHQDKMGGMDALHAAGIATYANALSNQLAP QEGLVAAQHSLTFAANGWVEPATAPNFGPLKVFYPGPGHTSDNITVGIDG TDIAFGGCLIKDSKAKSLGNLGDADTEHYAASARAFGAAFPKASMIVMSH SAPDSRAAITHTARMADKLR SEQ ID No. 1080 MELPNIMHPVAKLSTALAAALMLSGCMPGEIRPTIGQQMETGDQRFGDLV FRQLAPNVWQHTSYLDMPGFGAVASNGLIVRDGGRVLVVDTAWTDDQTAQ ILNWIKQEINLPVALAVVTHAHQDKMGGMDALHAAGIATYANALSNQLAP QEGMVAAQHSLTFAANGWVEPATAPNFGPLKVFYPGPGHTSDNITVGIDG TDIAFGGCLIKDSKAKSLGNLGDADTEHYAASARAFGAAFPKASMIVMSH SAPDSRAAITHTARMADKLR

said peptides being chosen, preferably, from the peptides of sequence SEQ ID No. 2 to SEQ ID No. 9 and SEQ ID No. 1083 as defined hereafter:

Peptide SEQ ID No. Amino acid sequence Position of the peptide in the NDM protein(s) SEQ ID AAITHTAR 257-264 for the proteins of SEQ No. 1, 1078, No. 2 1079, 1080 SEQ ID AFGAAFPK 235-242 for the proteins of SEQ No. 1, 1078, No. 3 1079, 1080 SEQ ID ASMIVMSHSAPDSR 243-256 for the proteins of SEQ No. 1, 1078, No. 4 1079, 1080 SEQ ID FGDLVFR 46-52 for the proteins of SEQ No. 1, 1078, No. 5 1079, 1080 SEQ ID MELPNIMHPVAK 1-12 for the proteins of SEQ No. 1, 1078, 1079, No. 6 1080 SEQ ID QEINLPVALAVVTHAHQDK 107-125 for the proteins of SEQ No. 1, 1078, No. 7 1079, 1080 SEQ ID SLGNLGDADTEHYAASAR 217-234 for the proteins of SEQ No. 1, 1078, No. 8 1079, 1080 SEQ ID VLVVDTAWTDDQTAQILNWIK 86-106 for the proteins of SEQ No. 1, 1078, No. 9 1080 SEQ ID LSTALAAALMLSGCMAGEIR 13-32 for the protein of SEQ No. 1078 No. 1081 SEQ ID LSTALAAALMLSGCMPGEIR 13-32 for the protein of SEQ No. 1, 1079, 1080 No. 1082 SEQ ID VLLVDTAWTDDQTAQILNWIK 86-106 for the protein of SEQ No. 1079 No. 1083

Preferably, the resistance markers are NDM markers, chosen from the peptides of sequence SEQ ID No. 2, SEQ ID No. 3, SEQ ID No. 5, or SEQ ID No. 7.

The detection of a mechanism of resistance to carbapenems induced by the expression of a KPC protein is characterised by the detection of at least one peptide belonging to a KPC protein and to its different sequence variants SEQ ID No. 10 to SEQ ID No. 19 and SEQ ID No. 1084 to SEQ ID No. 1093.

SEQ ID No. 10: MSLYRRLVLLSCLSWPLAGFSATALTNLVAEPFAKLEQDFGGSIGVYAMD TGSGATVSYRAEERFPLCSSFKGFLAAAVLARSQQQAGLLDTPIRYGKNA LVPWSPISEKYLTTGMTVAELSAAAVQYSDNAAANLLLKELGGPAGLTAF MRSIGDTTFRLDRWELELNSAIPGDARDTSSPRAVTESLQKLTLGSALAA PQRQQFVDWLKGNTTGNHRIRAAVPADWAVGDKTGTCGVYGTANDYAVVW PTGRAPIVLAVYTRAPNKDDKHSEAVIAAAARLALEGLGVNGQ SEQ ID No. 11: MSLYRRLVLLSCLSWPLAGFSATALTNLVAEPFAKLEQDFGGSIGVYAMD TGSGATVSYRAEERFPLCSSFKGFLAAAVLARSQQQAGLLDTPIRYGKNA LVPWSPISEKYLTTGMTVAELSAAAVQYSDNAAANLLLKELGGPAGLTAF MRSIGDTTFRLDRWELELNSAIPGDARDTSSPRAVTESLQKLTLGSALAA PQRQQFVDWLKGNTTGNHRIRAAVPADWAVGDKTGTCGVYGTANDYAVVW PTGRAPIVLAVYTRAPNKDDKYSEAVIAAAARLALEGLGVNGQ SEQ ID No. 12: MSLYRRLVLLSCLSWPLAGFSATALTNLVAEPFAKLEQDFGGSIGVYAMD TGSGATVSYRAEERFPLCSSFKGFLAAAVLARSQQQAGLLDTPIRYGKNA LVRWSPISEKYLTTGMTVAELSAAAVQYSDNAAANLLLKELGGPAGLTAF MRSIGDTTFRLDRWELELNSAIPGDARDTSSPRAVTESLQKLTLGSALAA PQRQQFVDWLKGNTTGNHRIRAAVPADWAVGDKTGTCGGYGTANDYAVVW PTGRAPIVLAVYTRAPNKDDKHSEAVIAAAARLALEGLGVNGQ SEQ ID No. 13: MSLYRRLVLLSCLSWPLAGFSATALTNLVAEPFAKLEQDFGGSIGVYAMD TGSGATVSYRAEERFPLCSSFKGFLAAAVLARSQQQAGLLDTPIRYGKNA LVRWSPISEKYLTTGMTVAELSAAAVQYSDNAAANLLLKELGGPAGLTAF MRSIGDTTFRLDRWELELNSAIPGDARDTSSPRAVTESLQKLTLGSALAA PQRQQFVDWLKGNTTGNHRIRAAVPADWAVGDKTGTCGVYGTANDYAVVW PTGRAPIVLAVYTRAPNKDDKHSEAVIAAAARLALEGLGVNGQ SEQ ID No. 14: MSLYRRLVLLSCLSWPLAGFSATALTNLVAEPFAKLEQDFGGSIGVYAMD TGSGATVSYRAEERFPLCSSFKGFLAAAVLARSQQQAGLLDTPIRYGKNA LVPWSPISEKYLTTGMTVAELSAAAVQYSDNAAANLLLKELGGPAGLTAF MRSIGDTTFRLDRWELELNSAIPGDARDTSSPRAVTESLQKLTLGSALAA PQRQQFVDWLKGNTTGNHRIRAAVPADWAVGDKTGTCGGYGTANDYAVVW PTGRAPIVLAVYTRAPNKDDKHSEAVIAAAARLALEGLGVNGQ SEQ ID No. 15: MSLYRRLVLLSCLSWPLAGFSATALTNLVAEPFAKLEQDFGGSIGVYAID TGSGATVSYRAEERFPLCSSFKGFLAAAVLARSQQQAGLLDTPIRYGKNA LVPWSPISEKYLTTGMTVAELSAAAVQYSDNAAANLLLKELGGPAGLTAF MRSIGDTTFRLDRWELELNSAIPGDARDTSSPRAVTESLQKLTLGSALAA PQRQQFVDWLKGNTTGNHRIRAAVPADWAVGDKTGTCGVYGTANDYAVVW PTGRAPIVLAVYTRAPNKDDKYSEAVIAAAARLALEGLGVNGQ SEQ ID No. 16: MSLYRRLVLLSCLSWPLAGFSATALTNLVAEPFAKLEQDFGGSIGVYAMD TGSGATVSYRAEERFPLCSSFKGFLAAAVLARSQQQAGLLDTPIRYGKNA LVPWSPISEKYLTTGMTVAELSAAAVQYSDNAAANLLLKELGGPAGLTAF MRSIGDTTFRLDRWELELNSAIPGDARDTSSPRAVTESLQKLTLGSALAA PQRQQFVDWLKGNTTGNHRIRAAVPADWAVGDKTGTCGGYGTANDYAVVW PTGRAPIVLAVYTRAPNKDDKYSEAVIAAAARLALEGLGVNGQ SEQ ID No. 17: MSLYRRLVLLSCLSWPLAGFSATALTNLVAEPFAKLEQDFGGSIGVYAMD TGSGATVSYRAEERFPLCSSFKGFLAAAVLARSQQQAGLLDTPIRYGKNA LVPWSPISEKYLTTGMTVAELSAAAVQYSDNAAANLLLKELGGPAGLTAF MRSIGDTTFRLDRWELELNSAIPGDARDTSSPRAVTESLQKLTLGSALAA PQRQQFVDWLKGNTTGNHRIRAAVPADWAVGDKTGTCGAYGTANDYAVVW PTGRAPIVLAVYTRAPNKDDKYSEAVIAAAARLALEGLG SEQ ID No. 18: MSLYRRLVLLSCLSWPLAGFSATALTNLVAEPFAKLEQDFGGSIGVYAMD TGSGATVSYRAEERFPLCSSFKGFLAAAVLARSQQQAGLLDTPIRYGKNA LVRWSPISEKYLTTGMTVAELSAAAVQYSDNAAANLLLKELGGPAGLTAF MRSIGDTTFRLDRWELELNSAIPGDARDTSSPRAVTESLQKLTLGSALAA PQRQQFVDWLKGNTTGNHRIRAAVPADWAVGDKTGTCGVYGTANDYAVVW PTGRAPIVLAVYTRAPNKDDKYSEAVIAAAARLALEGLGVNGQ SEQ ID No. 19: MSLYRRLVLLSCLSWPLAGFSATALTNLVAEPFAKLEQDFGGSIGVYAMD TGSGATVSYRAEERFPLCSSFKGFLAAAVLARSQQQAGLLDTPIRYGKNA LVLWSPISEKYLTTGMTVAELSAAAVQYSDNAAANLLLKELGGPAGLTAF MRSIGDTTFRLDRWELELNSAIPGDARDTSSPRAVTESLQKLTLGSALAA PQRQQFVDWLKGNTTGNHRIRAAVPADWAVGDKTGTCGVYGTANDYAVVW PTGRAPIVLAVYTRAPNKDDKHSEAVIAAAARLALEGLGVNGQ SEQ ID No. 1084 MSLYRRLVLLSCLSWPLAGFSATALTNLVAEPFAKLEQDFGGSIGVYAMD TGSGATVSYRAEERFPLCSSFKGFLAAAVLARSQQQAGLLDTPIRYGKNA LVPWSPISEKYLTTGMTVAELSAAAVQYSDNAAANLLLKELGGPAGLTAF MRSIGDTTFRLDRWELELNSAIPGDARDTSSPRAVTESLQKLTLGSALAA PQRQQFVDWLKGNTTGNHRIRAAVPADWAVGDKTGTCGGYGTANDYAVVW PTGRAPIVLAVYTRAPNKDDKHSEAVIAAAARLALEGLGVNGQ SEQ ID No. 1085 MSLYRRLVLLSCLSWPLAGFSATALTNLVAEPFAKLEQDFGGSIGVYAMD TGSGATVSYRAEERFPLCSSFKGFLAAAVLARSQQQAGLLDTPIRYGKNA LVPWSPISEKYLTTGMTVAELSAAAVQYSDNAAANLLLKELGGPAGLTAF MRSIGDTTFRLDRWELELNSAIPGDARDTSSPRAVTESLQKLTLGSALAA PQRQQFVDWLKGNTTGNHRIRAAVPADWAVGDKTGTCGGYGTANDYAVVW PTGRAPIVLAVYTRAPNKDDKYSEAVIAAAARLALEGLGVNGQ SEQ ID No. 1086 MSLYRRLVLLSCLSWPLAGFSATALTNLVAEPFAKLEQDFGGSIGVYAMD TGSGATVSYRAEERFPLCSSFKGFLAAAVLARSQQQAGLLDTPIRYGKNA LVPWSPISEKYLTTGMTVAELSAAAVQYSDNAAANLLLKELGGPAGLTAF MRSIGDTTFRLDRWELELNSAIPGDARDTSSPRAVTESLQKLTLGSALAA PQRQQFVDWLKGNTTGNHRIRAAVPADWAVGDKTGTCGVYGTANDYAVVW PTGRAPIVLAVYTRAPNKDDKHSEAVIAAAARLALEGLGVNGQ SEQ ID No. 1087 MSLYRRLVLLSCLSWPLAGFSATALTNLVAEPFAKLEQDFGGSIGVYAMD TGSGATVSYRAEERFPLCSSFKGFLAAAVLARSQQQAGLLDTPIRYGKNA LVPWSPISEKYLTTGMTVAELSAAAVQYSDNAAANLLLKELGGPAGLTAF MRSIGDTTFRLDRWELELNSAIPGDARDTSSPRAVTESLQKLTLGSALAA PQRQQFVDWLKGNTTGNHRIRAAVPADWAVGDKTGTCGVYGTANDYAVVW PTGRAPIVLAVYTRAPNKDDKYSEAVIAAAARLALEGLGVNGQ SEQ ID No. 1088 MSLYRRLVLLSCLSWPLAGFSATALTNLVAEPFAKLEQDFGGSIGVYAMD TGSGATVSYRAEERFPLCSSFKGFLAAAVLARSQQQAGLLDTPIRYGKNA LVPWSPISEKYLTTGMTVAELSAAAVQYSDNAAANLLLKELGGPAGLTAF MRSIGDTTFRLDRWELELNSAIPSDARDTSSPRAVTESLQKLTLGSALAA PQRQQFVDWLKGNTTGNHRIRAAVPADWAVGDKTGTCGVYGTANDYAVVW PTGRAPIVLAVYTRAPNKDDKHSEAVIAAAARLALEGLGVNGQ SEQ ID No. 1089 MSLYRRLVLLSCLSWPLAGFSATALTNLVAEPFAKLEQDFGGSIGVYAMD TGSGATVSYRAEERFPLCSSFKGFLAAAVLARSQQQAGLLDTPIRYGKNA LVPWSPISEKYLTTGMTVAELSAAAVQYSDNAAANLLLKELGGPAGLTAF MRSIGDTTFRLDRWELEMNSAIPGDARDTSSPRAVTESLQKLTLGSALAA PQRQQFVDWLKGNTTGNHRIRAAVPADWAVGDKTGTCGVYGTANDYAVVW PTGRAPIVLAVYTRAPNKDDKHSEAVIAAAARLALEGLGVNGQ SEQ ID No. 1090 MSLYRRLVLLSCLSWPLAGFSATALTNLVAEPFAKLEQDFGGSIGVYAMD TGSGATVSYRAEERFPLCSSFKGFLAAAVLARSQQQAGLLDTPIRYGKNA LVRWSPISEKYLTTGMTVAELSAAAVQYSDNAAANLLLKELGGPAGLTAF MRSIGDTTFRLDRWELELNSAIPGDARDTSSPRAVTESLQKLTLGSALAA PQRQQFVDWLKGNTTGNHRIRAAVPADWAVGDKTGTCGVYGTANDYAVVW PTGRAPIVLAVYTRAPNKDDKHSEAVIAAAARLALEGLGVNGQ SEQ ID No. 1091 MSLYRRLVLLSCLSWPLAGFSATALTNLVAEPFAKLEQDFGGSIGVYAMD TGSGATVSYRAEERFPLCSSFKGFLAAAVLARSQQQAGLLDTPIRYGKNA LVRWSPISEKYLTTGMTVAELSAAAVQYSDNAAANLLLKELGGPAGLTAF MRSIGDTTFRLDRWELELNSAIPGDARDTSSPRAVTESLQKLTLGSALAA PQRQQFVDWLKGNTTGNHRIRAAVPADWAVGDKTGTCGVYGTANDYAVVW PTGRAPIVLAVYTRAPNKDDKYSEAVIAAAARLALEGLGVNGQ SEQ ID No. 1092 RLVLLSCLSWPLAGFSATALTNLVAEPFAKLEQDFGGSIGVYAMDTGSGA TVSYRAEERFPLCSSFKGFLAAAVLARSQQQAGLLDTPIRYGKNALVPWS PISEKYLTTGMTVAELSAAAVQYSDNAAANLLLKELGGPAGLTAFMRSIG DTTFRLDRWELELNSAIPGDARDTSSPRAVTESLQKLTLGSALAAPQRQQ FVDWLKGNTTGNHRIRAAVPADWAVGDKTGTCGAYGTANDYAVVWPTGRA PIVLAVYTRAPNKDDKYSEAVIAAAARLALEGLG SEQ ID No. 1093 SLYRRLVLLSCLSWPLAGFSATALTNLVAEPFAKLEQDFGGSIGVYAMDT GSGATVSYRAEERFPLCSSFKGFLAAAVLARSQQQAGLLDTPIRYGKNAL VRWSPISEKYLTTGMTVAELSAAAVQYSDNAAANLLLKELGGPAGLTAFM RSIGDTTFRLDRWELELNSAIPGDARDTSSPRAVTESLQKLTLGSALAAP QRQQFVDWLKGNTTGNHRIRAAVPADWAVGDKTGTCGGYGTANDYAVVWP TGRAPIVLAVYTRAPNKDDKHSEAVIAAAARLALEGLGVNGQ

said peptides being chosen, preferably, from the peptides of sequence SEQ ID No. 20 to SEQ ID No. 33 and SEQ ID No. 1094 to SEQ ID No. 1097 as defined hereafter:

Peptide SEQ ID No. Amino acid sequence Position of the peptide in the KPC protein(s) SEQ AAVPADWAVGDK 221-232 for the protein of SEQ No. 1093; 222-233 for the ID No. proteins of sequence SEQ ID No. 10, 11, 12, 13, 14, 15, 16, 20 17, 18, 19, 1084, 1085, 1086, 1087, 1088, 1089, 1090, 1091, 1092 SEQ APIVLAVYTR 254-263 for the protein of SEQ No. 1093; 255-264 for the ID No. proteins of sequence SEQ ID No. 10, 11, 12, 13, 14, 15, 16, 21 17, 18, 19, 1084, 1085, 1086, 1087, 1088, 1089, 1090, 1091, 1092 SEQ AVTESLQK 183-190 for the protein of SEQ No. 1093; 184-191 for the ID No. proteins of sequence SEQ ID No. 10, 11, 12, 13, 14, 15, 16, 22 17, 18, 19, 1084, 1085, 1086, 1087, 1088, 1089, 1090, 1091, 1092 SEQ ELGGPAGLTAFMR 139-151 for the protein of SEQ No. 1093; 140-152 for the ID No. proteins of sequence SEQ ID No. 10, 11, 12, 13, 14, 15, 16, 23 17, 18, 19, 1084, 1085, 1086, 1087, 1088, 1089, 1090, 1091, 1092 SEQ FPLCSSFK 64-71 for the protein of SEQ No. 1093; 65-72 for the ID No. proteins of sequence SEQ ID No. 10, 11, 12, 13, 14, 15, 16, 24 17, 18, 19, 1084, 1085, 1086, 1087, 1088, 1089, 1090, 1091, 1092 SEQ GFLAAAVLAR 72-81 for the protein of SEQ No. 1093; 73-82 for the ID No. proteins of sequence SEQ ID No. 10, 11, 12, 13, 14, 15, 16, 25 17, 18, 19, 1084, 1085, 1086, 1087, 1088, 1089, 1090, 1091, 1092 SEQ GNTTGNHR 211-218 for the protein of SEQ No. 1093; 212-219 for the ID No. proteins of sequence SEQ ID No. 10, 11, 12, 13, 14, 15, 16, 26 17, 18, 19, 1084, 1085, 1086, 1087, 1088, 1089, 1090, 1091, 1092 SEQ LALEGLGVNGQ 282-292 for the protein of SEQ No. 1093; 283-293 for the ID No. proteins of sequence SEQ ID No. 10, 11, 12, 13, 14, 15, 16, 27 18, 19, 1084, 1085, 1086, 1087, 1088, 1089, 1090, 1091 SEQ LTLGSALAAPQR 191-202 for the protein of SEQ No. 1093; 192-203 for the ID No. proteins of sequence SEQ ID No. 10, 11, 12, 13, 14, 15, 16, 28 17, 18, 19, 1084, 1085, 1086, 1087, 1088, 1089, 1090, 1091, 1092 SEQ NALVPWSPISEK 94-105 for the protein of SEQ No. 1092; 99-110 for the ID No. proteins of sequence SEQ ID No. 10, 11, 14, 15, 16, 17, 29 1084, 1085, 1086, 1087, 1088, 1089 SEQ QQFVDWLK 203-210 for the protein of SEQ No. 1093; 204-211 for the ID No. proteins of sequence SEQ ID No. 10, 11, 12, 13, 14, 15, 16, 30 17, 18, 19, 1084, 1085, 1086, 1087, 1088, 1089, 1090, 1091, 1092 SEQ SIGDTTFR 152-159 for the protein of SEQ No. 1093; 153-160 for the ID No. proteins of sequence SEQ ID No. 10, 11, 12, 13, 14, 15, 16, 31 17, 18, 19, 1084, 1085, 1086, 1087, 1088, 1089, 1090, 1091, 1092 SEQ SQQQAGLLDTPIR 82-94 for the protein of SEQ No. 1093; 83-95 for the ID No. proteins of sequence SEQ ID No. 10, 11, 12, 13, 14, 15, 16, 32 17, 18, 19, 1084, 1085, 1086, 1087, 1088, 1089, 1090, 1091, 1092 SEQ WELELNSAIPGDAR 163-176 for the protein of SEQ No. 1093; 164-177 for the ID No. proteins of sequence SEQ ID No. 10, 11, 12, 13, 14, 15, 16, 33 17, 18, 19, 1084, 1085, 1086, 1087, 1090, 1091, 1092 SEQ NALVR 98-102 for the proteins of SEQ No. 1093; 99-103 for the ID No. proteins of sequence SEQ ID No. 12, 13, 18, 1090, 1091 1094 SEQ TGTCGAYGTANDYAVVWPTGR 229-249 for the protein of SEQ No. 1092; 234-254 for the ID No. protein of sequence SEQ ID No. 17 1095 SEQ WELELNSAIPSDAR 164-177 for the protein of SEQ No. 1088 ID No. 1096 SEQ WELEMNSAIPGDAR 164-177 for the protein of SEQ No. 1089 ID No. 1097

Preferably, the resistance markers are KPC markers, chosen from the peptides of sequence SEQ ID No. 20, SEQ ID No. 21, SEQ ID No. 23, SEQ ID No. 25, SEQ ID No. 28, SEQ ID No. 29, SEQ ID No. 31, or SEQ ID No. 32.

The detection of a mechanism of resistance to carbapenems and/or to cephalosporins induced by the expression of a GES protein is characterised by the detection of at least one peptide belonging to a GES protein and to its different sequence variants SEQ ID No. 34 to SEQ ID No. 50.

SEQ ID No. 34: MRFIHALLLAGIAHSAYASEKLTFKTDLEKLEREKAAQIGVAIVDPQGEI VAGHRMAQRFAMCSTFKFPLAALVFERIDSGTERGDRKLSYGPDMIVEWS PATERFLASGHMTVLEAAQAAVQLSDNGATNLLLREIGGPAAMTQYFRKI GDSVSRLDRKEPEMGDNTPGDLRDTTTPIAMARTVAKVLYGGALTSTSTH TIERWLIGNQTGDATLRAGFPKDWVVGEKTGTCANGGRNDIGFFKAQERD YAVAVYTTAPKLSAVERDELVASVGQVITQLILSTDK SEQ ID No. 35: MRFIHALLLAGIAHSAYASEKLTFKTDLEKLEREKAAQIGVAIVDPQGEI VAGHRMAQRFAMCSTFKFPLAALVFERIDSGTERGDRKLSYGPDMIVKWS PATERFLASGHMTVLEAAQAAVQLSDNGATNLLLREIGGPAAMTQYFRKI GDSVSRLDRKEPEMGDNTPGDLRDTTTPIAMARTVAKVLYGGALTSTSTH TIERWLIGNQTGDATLRAGFPKDWVVGEKTGTCANGGRNDIGFFKAQERD YAVAVYTTAPKLSAVERDELVASVGQVITQLILSTDK SEQ ID No. 36: MRFIHALLLAGIAHSAYASEKLTFKTDLEKLEREKAAQIGVAIVDPQGEI VAGHRMAQRFAMCSTFKFPLAALVFERIDSGTERGDRKLSYGPDMIVEWS PATERFLASGHMTVLEAAQLAVQLSDNGATNLLLREIGGPAAMTQYFRKI GDSVSRLDRKEPEMGDNTPGDLRDTTTPIAMARTVAKVLYGGALTSTSTH TIERWLIGNQTGDATLRAGFPKDWVVGEKTGTCANGGRNDIGFFKAQERD YAVAVYTTAPKLSAVERDELVASVGQVITQLILSTDK SEQ ID No. 37: MRFIHALLLAGIAHSAYASEKLTFKTDLEKLEREKAAQIGVAIVDPQGEI VAGHRMAQRFAMCSTFKFPLAALVFERIDSGTERGDRKLSYGPDMIVEWS PATERFLASGHMTVLEAAQAAVQLSDNGATNLLLREIGGPAAMTQYFRKI GDSVSRLDRKEPEMNDNTPGDLRDTTTPIAMARTVAKVLYGGALTSTSTH TIERWLIGNQTGDATLRAGFPKDWVVGEKTGTCANGGRNDIGFFKAQERD YAVAVYTTAPKLSAVERDELVASVGQVITQLILSTDK SEQ ID No. 38: MRFIHALLLAGIAHSAYASEKLTFKTDLEKLEREKAAQIGVAIVDPQGEI VAGHRMAQRFAMCSTFKFPLAALVFERIDSGTERGDRKLSYGPDMIVEWS PATERFLASGHMTVLEAAQAAVQLSDNGATNLLLREIGGPAAMTQYFRKI GDSVSRLDRKEPEMSDNTPGDLRDTTTPIAMARTVAKVLYGGALTSTSTH TIERWLIGNQTGDATLRAGFPKDWVVGEKTGTCANGGRNDIGFFKAQERD YAVAVYTTAPKLSAVERDELVASVGQVITQLILSTDK SEQ ID No. 39: MRFIHALLLAGIAHSAYASEKLTFKTDLEKLEREKAAQIGVAIVDPQGEI VAGHRMAQRFAMCSTFKFPLAALVFERIDSGTERGDRKLSYGPDMIVKWS PATERFLASGHMTVLEAAQAAVQLSDNGATNLLLREIGGPAAMTQYFRKI GDSVSRLDRKEPEMSDNTPGDLRDTTTPIAMARTVAKVLYGGALTSTSTH TIERWLIGNQTGDATLRAGFPKDWVVGEKTGTCANGGRNDIGFFKAQERD YAVAVYTTAPKLSAVERDELVASVGQVITQLILSTDK SEQ ID No. 40: MRFIHALLLAGIAHSAYASEKLTFKTDLEKLEREKAAQIGVAIVDPQGEI VAGHRMAQRFAMCSTFKFPLAALVFERIDSGTERGDRKLSYGPDMIVEWS PATERFLASGHMTVLEAAQAAVQLSDNGATNLLLREIGGPAAMTQYFRKI GDSVSRLDRKEPEMGDNTPGDLRDTTTPIAMARTVAKVLYGGALTSTSTH TIERWLIGNQTGDATLRAGFPKDWVVGEKTGTCANGSRNDIGFFKAQERD YAVAVYTTAPKLSAVERDELVASVGQVITQLILSTDK SEQ ID No. 41: MRFIHALLLAGIAHSAYASEKLTFKTDLEKLEREKAAQIGVAIVDPQGEI VAGHRMAQRFAMCSTFKFPLAALVFERIDSGTERGDRKLSYGPDMIVEWS PATERFLASGHMTVLEAAQAAVQLSDNGATNLLLREIGGPAAMTQYFRKI GDSVSRLDRKEPEMGDNTPGDLRDTTTPIAMARTVAKVLYGGALTSTSTH TIERWLIGNQTGDATLRAGFPKDWVVGEKTGTCANGARNDIGFFKAQERD YAVAVYTTAPKLSAVERDELVASVGQVITQLILSTDK SEQ ID No. 42: MRFIHALLLAGTAHSAYASEKLTFKTDLEKLEREKAAQIGVAIVDPQGEI VAGHRTAQRFAMCSTFKFPLAALVFERIDSGTERGDRKLSYGPDMIVEWS PATERFLASGHMTVLEAAQAAVQLCDNGATNLLLREIGGPAAMTQYFRKI GDSVSRLDRKEPEMGDNTPGDLRDTTTPIAMARTVAKVLYGGALTSTSTH TIERWLIGNQTGDATLRAGFPKDWVVGEKTGTCANGGRNDIGFFKAQERD YAVAVYTTAPKLSAVERDELVASVGQVITQLILSTDK SEQ ID No. 43: MRFIHALLLAGIAHSAYASEKLTFKTDLEKLEREKAAQIGVAIVDPQGEI VAGHRMAQRFAMCSTFKFPLAALVFERIDSGTERGDRKLSYGPDMIVKWS PATERFLASGHMTVLEAAQAAVQLSDNGATNLLLREIGGPAAMTQYFRKI GDSVSRLDRKEPEMNDNTPGDLRDTTTPIAMARTVAKVLYGGALTSTSTH TIERWLIGNQTGDATLRAGFPKDWVVGEKTGTCANGGRNDIGFFKAQERD YAVAVYTTAPKLSAVERDELVASVGQVITQLILSTDK SEQ ID No. 44: MRFIHALLLAGIAHSAYASEKLTFKTDLEKLEREKAAQIGVAIVDPQGEI VAGHRMAQRFAMCSTFKFPLAALVFERIDSGTERGDRKLSYGPDMIVEWS PATERFLASGHMTVLEAAQAAVQLSDNGATNLLLREIGGPAAMTQYFRKI GDSVSRLDRKESEMSDNTPGDLRDTTTPIAMARTVAKVLYGGALTSTSTH TIERWLIGNQTGDATLRAGFPKDWVVGEKTGTCANGGRNDIGFFKAQERD YAVAVYTTAPKLSAVERDELVASVGQVITQLILSTDK SEQ ID No. 45: MRFIHALLLAGIAHSAYASEKLTFKTDLEKLEREKAAQIGVAIVDPQGEI VAGHRMAQRFAMCSTFKFPLAALVFERIDSGTERGDRKLSYGPDMIVEWS PATERFLASGHMTVLEAAQAAVQLSDNGATNLLLREIGGPAAMTQYFRKI GDSVSRLDRKEPEMSDNTPGDLRDTTTPIAMARTVAKVLYGGALTSTSTH TIERWLIGNQTGDATLRAGFPKDWVVGEKTGTCANGARNDIGFFKAQERD YAVAVYTTAPKLSAVERDELVASVGQVITQLILSTDK SEQ ID No. 46: MRFIHALLLAGIAHSAYASEKLTFKTDLEKLEREKAAEIGVAIVDPQGEI VAGHRMAQRFAMCSTFKFPLAALVFERIDSGTERGDRKLSYGPDMIVEWS PATERFLASGHMTVLEAAQAAVQLSDNGATNLLLREIGGPAAMTQYFRKI GDSVSRLDRKEPEMSDNTPGDLRDTTTPIAMARTVAKVLYGGALTSTSTH TIERWLIGNQTGDATLRAGFPKDWVVGEKTGTCANGGRNDIGFFKAQERD YAVAVYTTAPKLSAVERDELVASVGQVITQLILSTDK SEQ ID No. 47: MRFIHALLLAGIAHSAYASEKLTFKTDLEKLEREKAAQIGVAIVDPQGEI VAGHRMAQRFAMCSTFKFPLAALVFERIDSGTERGDRKLSYGPDMIVKWS PATERFLASGHMTVLEAAQAAVQLSDNGATNLLLREIGGPAAMTQYFRKI GDSVSRLDRKEPEMGDNTPGDLRDTTTPIAMARTVAKVLYGGALTSTSTH TIERWLIGNQTGDATLRAGFPKDWVVGEKTGTCANGARNDIGFFKAQERD YAVAVYTTAPKLSAVERDELVASVGQVITQLILSTDK SEQ ID No. 48: MRFIHALLLAGIAHSAYASEKLTFKTDLEKLEREKAAQIGVAIVDPQGEI VAGHRTAQRFAMCSTFKFPLAALVFERIDSGTERGDRKLSYGPDMIVKWS PATERFLASGHMTVLEAAQAAVQLSDNGATNLLLREIGGPAAMTQYFRKI GDSVSRLDRKEPEMGDNTPGDLRDTTTPIAMARTVAKVLYGGALTSTSTH TIERWLIGNQTGDATLRAGFPKDWVVGEKTGTCANGGRNDIGFFKAQERD YAVAVYTTAPKLSAVERDELVASVGQVITQLILSTDK SEQ ID No. 49: MRFIHALLLAGIAHSAYASEKLTFKTDLEKLEREKAAQIGVAIVDPQGEI VAGHRTAQRFAMCSTFKFPLAALVFERIDSGTERGDRKLSYGPDMIVKWS PATERFLASGHMTVLEAAQAAVQLSDNGATNLLLREIGGPAAMTQYFRKI GDSVSRLDRKEPEMSDNTPGDLRDTTTPIAMARTVAKVLYGGALTSTSTH TIERWLIGNQTGDATLRAGFPKDWVVGEKTGTCANGGRNDIGFFKAQERD YAVAVYTTAPKLSAVERDELVASVGQVITQLILSTDK SEQ ID No. 50: MRFIHALLLAGIAHSAYASEKLTFKTDLEKLEREKAAQIGVAIVDPQGEI VAGHRMAQRFAMCSTFKFPLAALVFERIDSGTERGDRKLSYGPDMIVEWS PATERFLASGHMTVLEAAQAAVQLSDNGATNLLLREIGGPAAMTQYFRKI GDSVSRLDRKEPEMGDNTPGDLRDTTTPIAMARTVAKVLYGGALTSTSTH TIERWLIGNQTGDATLRAGFPKDWVVGEKTGACANGARNDIGFFKAQERD YAVAVYTTAPKLSAVERDELVASVGQVITQLILSTDK

said peptides being chosen, preferably, from the peptides of sequence SEQ ID No. 51 to SEQ ID No. 79 as defined hereafter:

Peptide SEQ ID Clinical No. Amino acid sequence Position of the peptide in the GES protein(s) interest SEQ ID AAEIGVAIVDPQGEIVAGHR 36-55 for the protein of SEQ No. 46 carba No. 51 SEQ ID AAQIGVAIVDPQGEIVAGHR 36-55 for the proteins of SEQ No. 34, 35, 36, 37, 38, ESBL No. 52 39, 40, 41, 42, 43, 44, 45, 47, 48, 49, 50 SEQ ID AGFPK 218-222 for the proteins of SEQ No. 34, 35, 36, 37, ESBL No. 53 38, 39, 40, 41, 42, 43, 44, 45, 46, 47, 48, 49, 50 SEQ ID DTTTPIAMAR 174-183 for the proteins of SEQ No. 34, 35, 36, 37, ESBL No. 54 38, 39, 40, 41, 42, 43, 44, 45, 46, 47, 48, 49, 50 SEQ ID DWVVGEK 223-229 for the proteins of SEQ No. 34, 35, 36, 37, ESBL No. 55 38, 39, 40, 41, 42, 43, 44, 45, 46, 47, 48, 49, 50 SEQ ID DYAVAVYTTAPK 250-261 for the proteins of SEQ No. 34, 35, 36, 37, ESBL No. 56 38, 39, 40, 41, 42, 43, 44, 45, 46, 47, 48, 49, 50 SEQ ID EIGGPAAMTQYFR 136-148 for the proteins of SEQ No. 34, 35, 36, 37, ESBL No. 57 38, 39, 40, 41, 42, 43, 44, 45, 46, 47, 48, 49, 50 SEQ ID EPEMGDNTPGDLR 161-173 for the proteins of SEQ No. 34, 35, 36, 40, ESBL No. 58 41, 42, 47, 48, 50 SEQ ID EPEMNDNTPGDLR 161-173 for the proteins of SEQ No. 37, 43 carba No. 59 SEQ ID EPEMSDNTPGDLR 161-173 for the proteins of SEQ No. 38, 39, 45, 46, carba No. 60 49 SEQ ID ESEMSDNTPGDLR 161-173 for the protein of SEQ No. 44 carba No. 61 SEQ ID FAMCSTFK 60-67 for the proteins of SEQ No. 34, 35, 36, 37, 38, ESBL No. 62 39, 40, 41, 42, 43, 44, 45, 46, 47, 48, 49, 50 SEQ ID FIHALLLAGTAHSAYASEK 3-21 for the proteins of SEQ No. 34, 35, 36, 37, 38, ESBL No. 63 39, 40, 41, 43, 44, 45, 46, 47, 48, 49, 50 SEQ ID FIHALLLAGTAHSAYASEK 3-21 for the protein of SEQ No. 42 carba No. 64 SEQ ID FPLAALVFER 68-77 for the proteins of SEQ No. 34, 35, 36, 37, 38, ESBL No. 65 39, 40, 41, 42, 43, 44, 45, 46, 47, 48, 49, 50 SEQ ID IDSGTER 78-84 for the proteins of SEQ No. 34, 35, 36, 37, 38, ESBL No. 66 39, 40, 41, 42, 43, 44, 45, 46, 47, 48, 49, 50 SEQ ID IGDSVSR 150-156 for the proteins of SEQ No. 34, 35, 36, 37, ESBL No. 67 38, 39, 40, 41, 42, 43, 44, 45, 46, 47, 48, 49, 50 SEQ ID LSAVER 262-267 for the proteins of SEQ No. 34, 35, 36, 37, ESBL No. 68 38, 39, 40, 41, 42, 43, 44, 45, 46, 47, 48, 49, 50 SEQ ID LSYGPDMIVEWSPATER 89-105 for the proteins of SEQ No. 34, 36, 37, 38, ESBL No. 69 40, 41, 42, 44, 45, 46, 50 SEQ ID LSYGPDMIVK 89-98 for the proteins of SEQ No. 35, 39, 43, 47, 48, carba No. 70 49 SEQ ID NDIGFEK 239-245 for the proteins of SEQ No. 34, 35, 36, 37, ESBL No. 71 38, 39, 40, 41, 42, 43, 44, 45, 46, 47, 48, 49, 50 SEQ ID TDLEK 26-30 for the proteins of SEQ No. 34, 35, 36, 37, 38, ESBL No. 72 39, 40, 41, 42, 43, 44, 45, 46, 47, 48, 49, 50 SEQ ID TGACANGAR 230-238 for the protein of SEQ No. 50 carba No. 73 SEQ ID TGTCANGAR 230-238 for the proteins of SEQ No. 41, 45, 47 carba No. 74 SEQ ID TGTCANGGR 230-238 for the proteins of SEQ No. 34, 35, 36, 37, ESBL No. 75 38, 39, 42, 43, 44, 46, 48, 49 SEQ ID TGTCANGSR 230-238 for the protein of SEQ No. 40 carba No. 76 SEQ ID VLYGGALTSTSTHTIER 188-204 for the proteins of SEQ No. 34, 35, 36, 37, ESBL No. 77 38, 39, 40, 41, 42, 43, 44, 45, 46, 47, 48, 49, 50 SEQ ID WLIGNQTGDATLR 205-217 for the proteins of SEQ No. 34, 35, 36, 37, ESBL No. 78 38, 39, 40, 41, 42, 43, 44, 45, 46, 47, 48, 49, 50 SEQ ID WSPATER 99-105 for the proteins of SEQ No. 34, 35, 36, 37, carba No. 79 38, 39, 40, 41, 42, 43, 44, 45, 46, 47, 48, 49, 50

In the clinical interest column, the ESBL and carba entries correspond to the GES beta-lactamase activities which the corresponding peptide makes it possible to detect. Therefore, the detection of a carba peptide will indicate the presence of a carbapenemase beta-lactamase capable of hydrolysing carbapenems.

If no peptide referred to as carba is detected, the detection of a peptide referred to as ESBL will indicate the presence of a beta-lactamase with an extended spectrum (ESBL) capable of hydrolysing penicillins, first-generation cephalosporins such as cephaloridine and cefalotin, and at least one antibiotic from the oxyimino-beta-lactam class such as cefotaxime, ceftazidime or monobactams such as aztreonam.

The detection of a mechanism of resistance to carbapenems induced by a GES protein is thus characterised by the detection of at least one resistance-marking carba peptide chosen from the sequences SEQ ID No. 51, 59, 60, 61, 64, 70, 73, 74, 76, 79.

The detection of a mechanism of resistance to carbapenems induced by the expression of an IMP protein is characterised by the detection of at least one peptide belonging to an IMP protein and to its different sequence variants SEQ ID No. 80 to SEQ ID No. 105.

SEQ ID No. 80: MSKLSVFFIFLFCSIATAAESLPDLKIEKLDEGVYVHTSFEEVNGVVGVV PKHGLVVLVNAEAYLIDTPFTAKDTEKLVTWFVERGYKIKGSISSHFHSD STGGIEWLNSRSIPTYASELTNELLKKDGKVQATNSFSGVNYWLVKNKIE VFYPGPGHTPDNVVVWLPERKILFGGCFIKPYGLGNLGDANIEAWPKSAK LLKSKYGKAKLWPSHSEVGDASLLKLTLEQAVKGLNESKKPSKPSN SEQ ID No. 81: MKKLSVFFMFLFCSIAASGEALPDLKIEKLDEGVYVHTSFEEVNGWGWPK HGLVVLVNTDAYLIDTPFTAKDTEKLVTVVFVERGYKIKGSISSHFHSDS TGGIEWLNSOSIPTYASELTNELLKKDGKVQAKNSFSGASYVVLVKKKIE IFYPGPGHTPDNVVVWLPEHRVLFGGCFVKPYGLGNLGDANLEAWPKSAK LLVSKYGKAKLVVPSHSEVGDASLLKRTLEQAVKGLNESKKLSKPSN SEQ ID No. 82: MSKLSVFFIFLFCSIATAAEPLPDLKIEKLDEGVYVHTSFEEVNGWGVVP KHGLVVLVDAEAYLIDTPFTAKDTEKLVTWFVERGYKIKGSISSHFHSDS TGGIEWLNSQSIPTYASELTNELLKKDGKVQAKNSFGGVNYVVLVKNKIE VFYPGPGHTPDNLVVWLPERKILFGGCFIKPYGLGNLGDANLEAWPKSAK LLISKYGKAKLVVPSHSEAGDASLLKLTLEQAVKGLNESKKPSKLSN SEQ ID No. 83: MKKLFVLCVCFLCSITAAGAALPDLKIEKLEEGVYVHTSFEEVNGWGVVS KHGLVVLVNTDAYLIDTPFTATDTEKLVNWFVERGYKIKGTISSHFHSDS TGGIEWLNSQSIPTYASELTNELLKKDGKVQAKNSFSGVSYWLVKNKIEV FYPGPGHTQDNVVVVVLPEKKILFGGCFVKPDGLGNLGDANLEAWPKSAK ILMSKYGKAKLVVSSHSEIGDASLLKRTWEQAVKGLNESKKPSQPSN SEQ ID No. 84: MSKLFVFFMFLFCSITAAAESLPDLKIEKLDEGVYVHTSFEEVNGWGWPK HGLVVLVNTEAYLIDTPFTAKDTEKLVTWFVERGYKIKGSISSHFHSDST GGIEWLNSQSIPTYASELTNELLKKDGKVQAKNSFSGASYVVLVKKKIEV FYPGPGHTPDNVVVWLPENRVLFGGCFVKPYGLGNLGDANVEAWPKSAKL LMSKYGKAKLVVPSHSEVGDASLLKRTLEQAVKGLNESKKPSKPSN SEQ ID No. 85: MSKLFVFFMFLFCSITAAGESLPDLKIEKLDEGVYVHTSFEEVNGWGVIP KHGLVVLVNTDAYLIDTPFTAKDTENLVNWFVERGYRIKGSISSHFHSDS TGGIEWLNSQSIPTYASELTNELLKKDGKVQAKYSFSGVSYVVLVKKKIE VFYPGPGHAPDNVVVWLPENRVLFGGCFVKPYGLGNLGDANLEAWPKSAK LLMSKYSKAKLWPSHSDIGDSSLLKLTVVEQTVKGFNESKKSTTAH SEQ ID No. 86: MKKLFVLCVFFFCNIAVAEESLPDLKIEKLEEGVYVHTSFEEVKGWSVVT KHGLVVLVKNDAYLIDTPITAKDTEKLVNWFVERGYKIKGSISTHFHGDS TAGIEVVLNSQSIPTYASELTNELLKKDNKVQAKHSFNGVSYSLIKNKIE VFYPGPGHTQDNVVVWLPEKKILFGGCFVKPDGLGYLGDANLEAINPKSA KILMSKYGKAKLVVSSHSDIGDVSLLKRTVVEQAVKGLNESKKSSQPSD SEQ ID No. 87: MNKLSVFFMFMFCSITAAGESLPDLKIEKLDEGVYVHTSFEEVNGVVGVV PKHGLVVLVNTEAYLIDTPFTAKDTEKLVTINFVERGYKIKGSISSHFHS DSTGGIEWLNSQSIPTYASELTNELLKKDGKVQAKNSFSGGSYINLVNNK IEVFYPGPGHTPDNVVVVVLPENRVLFGGCFVKPYGLGNLGDANLEAWPK SAKILMSKYGKAKLVVSSHSETGNASLLKLTWEQAVKGLKESKKPSLPSN SEQ ID No. 88: MKKLFVLCVFFLCNIAAADDSLPDLKIEKLEKGVYVHTSFEEVKGWGVVT KHGLVVLVKNDAYLIDTPITAKDTEKLVNINFIEHGYRIKGSISTHFHGD STAGIEWLNSQSISTYASELTNELLKKDNKVQATNSFSGVSYSLIKNKIE VFYPGPGHTQDNVVVVVLPEKKILFGGCFVKPDGLGNLGDANLEAWPKSA KILMSKYGKAKLVVSSHSEIGNASLLQRTVVEQAVKGLNESKKPLQPSS SEQ ID No. 89: MKKLFVLCVFLFCSITAAGESLPDLKIEKLEEGVYVHTSFEEVNGWGVVS KHGLVILVNTDAYLIDTPFTAKDTEKLVTVVFVERGYKIKGSISSHFHSD STGGIEWLNSQSIPTYASELTNDLLKQNGKVQAKNSFSGVSYVVLVKNKI EVFYPGPGHTQDNVVVINLPEKKILFGGCFVKPYGLGNLDDANVVAWPHS AEILMSRYGNAKLVVPSHSDIGDASLLKLTWEQAVKGLKESKKPSEPSN SEQ ID No. 90: MSKLSVFFIFLFCSIATAAESLPDLKIEKLDEGVYVHTSFKEVNGWGVVP KHGLVVLVNAEAYLIDTPFTAKDTEKLVTVVFVERGYKIKGSISSHFHSD STGGIEWLNSRSIPTYASELTNELLKKDGKVQATNSFSGVNYVVLVKNKI EVFYPGPGHTPDNVWVVLPERKILFGGCFIKPYGLGNLGDANIEAWPKSA KLLKSKYGKAKLVVPSHSEVGDASLLKLTLEQAVKGLNESKKPSKPSN SEQ ID No. 91: MKKLFVLCVCFLCSITAAGAALPDLKIEKLEEGVYVHTSFEEVNGWGVVS KHGLVVLVNTDAYLIDTPFTATDTEKLVNWFVERGYKIKGTISSHFHSDS TGGIEWLNSQSIPTYASELTNELLKKDGKVQAKNSFSGVSYVVLVKNKIE VFYPGPGHTQDNVVVWLPEKKILFGGCFVKPDGLGNLGDANLEAWPKSAK ILMSKYVKAKLVVSSHSEIGDASLLKRTWEQAVKGLNESKKPSQPSN SEQ ID No. 92: MKKLFVLCVCFLCSITAAGAALPDLKIEKLEEGVYVHTSFEEVNGWGWSK HGLVVLVNTDAYLIDTPFTATDTEKLVNWFVERGYKIKGTISSHFHSDST GGIEWLNSQSIPTYASELTNELLKKDGKVQAKNSFSGVSYWLVKNKIEVF YPGPGHTQDNVVVWLPEKKILFGGCFVKPDGLGNLGDANLEAWPKSAKIL MSKYGKAKLVVSSHSEIGDASLLKRTWEQAVKGLNESRKPSQPSN SEQ ID No. 93: MSKLSVFFIFLFCSIATAAESLPDLKIEKLDEGVYVHTSFEEVNGWGVVP KHGLVVLVNAEAYLIDTPFTAKDTEKLVTVVFVERGYKIKGSISSHFHSD STGGIEWLNSRSIPTYASELTNELLKKDGKVQATNSFSGVNYVVLVKNKI EVFYPGPGHTPDNVVVWLPERKILFGGCFlKPYGLGNLSDANIEAWPKSA KLLKSKYGKAKLVVPGHSEVGDASLLKLTLEQAVKGLNESKKPSKPSN SEQ ID No. 94: MSKLSVFFIFLFCSIATAAEPLPDLKIEKLDEGVYVHTSFEEVNGWGVFP KHGLVVLVDAEAYLIDTPFTAKDTEKLVIVVFVERGYKIKGSISSHFHSD STGGIEWLNSQSIPTYASELTNELLKKDGKVQAKNSFGGVNYWLVKNKIE VFYPGPGHTPDNLVVVVLPERKILFGGCFIKPYGLGNLGDANLEAWPKSA KLLISKYGKAKLVVPSHSEAGDASLLKLTLEQAVKGLNESKKPSKLSN SEQ ID No. 95: MKKLFVLCVFVFCSITVAGETLPNLRVEKLEEGVYVHTSYEEVKGWGVVT KHGLVVLIGADAYLIDTPFTAKDTEKLVNWFVERGYKIKGTVSSHFHSDS TGGIEWLNSQSIPTYASELTNELLKKDGKVQAKNSFDGVSYVVLAKDKIE VFYPGPGHTQDNVVVWLPEKEILFGGCFVKPHGLGNLGDANLEAWPESAK ILMEKYGKAKLVVSGHSETGDATHLKRTWEQAVKGLKESKKTLQPSN SEQ ID No. 96: MSKLSVFFIFLFCSIATAAESLPDLKIEKLDEGVYVHTSFEEVNGWGVVP KHGLVVLVNAEAYLIDTPFTAKDTEKLVTWFVERGYKIKGSISSHFHSDS TGGIGWLNSRSIPTYASELTNELLKKDGKVQATNSFSGVNYWLVKNKIEV FYPGPGHTPDNVVVWLPERKILFGGCFIKPYGLGNLGDANIEAWPKSAKL LKSKYGKAKLVVPGHSEVGDASLLKLTLEQAVKGLNESKKPSKPSN SEQ ID No. 97: MSKLSVFFIFLFCSIATAAESLPDLKIEKLDEGVYVHTSFEEVNGWGVVP KHGLVVLVNAEAYLIDTPFTAKDTEKLVIWFVERGYKIKGSISSHFHSDS TGGIEWLNSRSIPTYASELTNELLKKDGKVQATNSFSGVNYWLVKNKIEV FYPGPGHTPDNVVVVVLPERKILFGGCFIKPYGLGNLGDANIEAWPKSAK LLKSKYGKAKLVVPGHSEVGDASLLKLTLEQAVKGLNESKKPSKPSN SEQ ID No. 98: MSKLSVFFIFLFCSIATAAESLPDLKIEKLDEGVYVHTSFEEVNGWGVFP KHGLVVLVNAEAYLIDTPFTAKDTEKLVTVVFVERGYKIKGSISSHFHSD STGGIEWLNSRSIPTYASELTNELLKKDGKVQATNSFSGVNYVVLVKNKI EVFYPGPGHTPDNVVINVLPERKILFGGCFIKPYGLGNLGDANIEAWPKS AKLLKSKYGKAKLVVPSHSEVGDASLLKLTLEQAVKGLNESKKPSKPSN SEQ ID No. 99: MKKLFVLCIFLFCSITAAGASLPDLKIEKLEEGVYVHTSFEEVNGWGVVS KHGLVVLVNTDAYLIDTPFTAKDTEKLVNWFVERGYKIKGSISSHFHSDS TGGIEWLNSQSIPTYASVLTNELLKKDGKVQAKNSFSGVSYWLVKNKIEV FYPGPGHTQDNVVVWLPKNKILFGGCFVKPYGLGNLDDANVEAWPHSAEK LISKYGNAKLVVPSHSDIGDASLLKLIVVEQAVKGLNESKKSNTVH SEQ ID No. 100: MKKLFVLCVCFLCSITAAGAALPDLKIEKLEEGVYVHTSFEEVNGWGVFS KHGLVVLVNTDAYLIDTPFTATDTEKLVNWFVERGYKIKGTISSHFHSDS TGGIEINLNSQSIPTYASELTNELLKKDGKVQAKNSFSGVSYVVLVKNKI EVFYPGPGHTQDNVVVVVLPEKKILFGGCFVKPDGLGNLGDANLEAVVPK SAKILMSKYVKAKLVVSSHSEIGDASLLKRTVVEQAVKGLNESKKPSQPS N SEQ ID No. 101: MKKLFVLCIFLFCSITAAGASLPDLKIEKLEEGVYVHTSFEEVNGVVGVA SKHGLVVLVNTDAYLIDTPFTAKDTEKLVNVVFVERGYKIKGSISSHFHS DSTGGIEWLNSQSIPTYASVLTNELLKKDGKVQAKNSFSGVSYVVLVKNK IEVFYPGPGHTQDNVVVVVLPKNKILFGGCFVKPYGLGNLDDANVEAINP HSAEKLISKYGNAKLVVPSHSDIGDASLLKLTVVEQAVKGLNESKKSNTV H SEQ ID No. 102: MKKLFVLCVCFLCSITAAGARLPDLKIEKLEEGVYVHTSFEEVNGVVGVV SKHGLVVLVNTDAYLIDTPFTATDTEKLVNWFVERGYKIKGTISSHFHSD STGGIEWLNSQSIPTYASELTNELLKKDGKVQAKNSFSGVSYVVLVKNKI EVFYPGPGHTQDNVVVWLPEKKILFGGCFVKPDGLGNLGDANLEAVVPKS AKILMSKYVKAKLVVSSHSEIGDASLLKRTVVEQAVKGLNESKKPSQPSN SEQ ID No. 103: MKKLFVLCIFLFLSITASGEVLPDLKIEKLEEGVYLHTSFEEVSGINGVV TKHGLVVLVNNDAYLIDTPFTNKDTEKLVAWFVGRGFTIKGSVSSHFHSD STGGIEWLNSQSIPTYASELTNELLKKNGKVQATNSFSGVSYWLVKNKIE IFYPGPGHTQDNVVVVVLPENKILFGGCFVKPDGLGNLDDANLKAWPKSA KILMSKYGKAKLWSGHSEIGNASLLKLTWEQAVKGLKESKKPLLPSN SEQ ID No. 104: MKKLFVLCVCFFCSITAAGAALPDLKIEKLEEGVFVHTSFEEVNGWGVVT KHGLWLVNTDAYLIDTPFTATDTEKLVNWFVERGYEIKGTISSHFHSDST GGIEWLNSQSIPTYASELTNELLKKSGKVQAKYSFSEVSYVVLVKNKIEV FYPGPGHTQDNLVVVVLPESKILFGGCFIKPHGLGNLGDANLEAWPKSAK ILMSKYGKAKLVVSSHSEKGDASLMKRTWEQALKGLKESKKTSSPSN SEQ ID No. 105: MKKLFVLCIFLFCSITAAGESLPDLKIEKLEDGVYVHTSFEEVNGWGVVT KHGLVFLVNTDAYLIDTPFAAKDTEKLVNWFVERGYKIKGSISSHFHSDS SGGIEWLNSQSIPTYASELTNELLKKNGKVQAKNSFSGVSYWLLKNKIEI FYPGPGHTQDNVVVWLPEKKILFGGCFVKPYGLGNLDDANVEAWPHSAEI LMSRYGNAKLVVPSHSDVGDASLLKLTANEQAVKGLKESKKPSQPSN

said peptides being chosen, preferably, from the peptides of sequence SEQ ID No. 106, SEQ ID No. 108 to SEQ ID No. 130, SEQ ID No. 133 to SEQ ID No. 173, SEQ ID No. 175 to SEQ ID No. 180, as defined hereafter:

Peptide SEQ ID Position of the peptide in the IMP No. Amino acid sequence protein(s) SEQ ID DTENLVNWFVER 73-84 for the protein of SEQ No. 85 No. 106 SEQ ID EILFGGCFVK 170-179 for the protein of SEQ No. 95 No. 107 SEQ ID EVNGWGVVPK 42-51 for the proteins of SEQ No. 80, 81, No. 108 82, 84, 87, 90, 93, 96, 97 SEQ ID GDASLMK 219-225 for the protein of SEQ No. 104 No. 109 SEQ ID GFNESK 234-239 for the protein of SEQ No. 85 No. 110 SEQ ID GFTIK 85-89 for the protein of SEQ No. 103 No. 111 SEQ ID GLNESK 234-239 for the proteins of SEQ No. 80, 81, No. 112 82, 83, 84, 86, 88, 90, 91, 93, 94, 96, 97, 98, 99, 100, 101, 102 SEQ ID GLNESR 234-239 for the protein of SEQ No. 92 No. 113 SEQ ID GSISSHFHSDSTGGIEWLNSR 90-110 for the proteins of SEQ No. 80, 90, No. 114 93, 97, 98 SEQ ID GSISSHFHSDSTGGIGWLNSR 90-110 for the protein of SEQ No. 96 No. 115 SEQ ID GVYVHTSFEEVK 33-44 for the proteins of SEQ No. 86, 88 No. 116 SEQ ID GWGVVTK 45-51 for the proteins of SEQ No. 88, 95, No. 117 103, 104, 105 SEQ ID GWSVVTK 45-51 for the protein of SEQ No. 86 No. 118 SEQ ID GYEIK 85-89 for the protein of SEQ No. 104 No. 119 SEQ ID HGLVFLVNTDAYLIDTPFAAK 52-72 for the protein of SEQ No. 105 No. 120 SEQ ID HGLVILVNTDAYLIDTPFTAK 52-72 for the protein of SEQ No. 89 No. 121 SEQ ID HGLVVLIGADAYLIDTPFTAK 52-72 for the protein of SEQ No. 95 No. 122 SEQ ID HGLVVLVDAEAYLIDTPFTAK 52-72 for the proteins of SEQ No. 82, 94 No. 123 SEQ ID HGLVVLVK 52-59 for the proteins of SEQ No. 86, 88 No. 124 SEQ ID HGLVVLVNAEAYLIDTPFTAK 52-72 for the proteins of SEQ No. 80, 90, No. 125 93, 96, 97, 98 SEQ ID HGLVVLVNNDAYLIDTPFTNK 52-72 for the protein of SEQ No. 103 No. 126 SEQ ID HGLVVLVNTDAYLIDTPFTAK 52-72 for the proteins of SEQ No. 81, 85, No. 127 99, 101 SEQ ID HGLVVLVNTEAYLIDTPFTAK 52-72 for the proteins of SEQ No. 84, 87 No. 128 SEQ ID HSFNGVSYSLIK 134-145 for the protein of SEQ No. 86 No. 129 SEQ ID IEVFYPGPGHTQDNVVVWLPK 148-168 for the proteins of SEQ No. 99, 101 No. 130 SEQ ID ILFGGCFIK 171-179 for the proteins of SEQ No. 80, 82, No. 131 90, 93, 94, 96, 97, 98, 104 SEQ ID ILFGGCFVK 171-179 for the proteins of SEQ No. 83, 86, No. 132 88, 89, 91, 92, 95, 99, 100, 101, 102, 103, 105 SEQ ID ILMEK 200-204 for the protein of SEQ No. 95 No. 133 SEQ ID ILMSK 200-204 for the proteins of SEQ No. 83, 86, No. 134 87, 88, 91, 92, 100, 102, 103, 104 SEQ ID LDEGVYVHTSFK 30-41 for the protein of SEQ No. 90 No. 135 SEQ ID LEEGVYVHTSFEEVK 30-44 for the protein of SEQ No. 86 No. 136 SEQ ID LEEGVYVHTSYEEVK 30-44 for the protein of SEQ No. 95 No. 137 SEQ ID LFVLCVCFLCSITAAGAR 4-21 for the protein of SEQ No. 102 No. 138 SEQ ID LLISK 200-204 for the proteins of SEQ No. 82, 94 No. 139 SEQ ID LLMSK 200-204 for the proteins of SEQ No. 84, 85 No. 140 SEQ ID LLVSK 200-204 for the protein of SEQ No. 81 No. 141 SEQ ID LPDLK 22-26 for the proteins of SEQ No. 80, 81, No. 142 82, 83, 84, 85, 86, 87, 88, 89, 90, 91, 92, 93, 94, 96, 97, 98, 99, 100, 101, 102, 103, 104, 105 SEQ ID LTLEQAVK 226-233 for the proteins of SEQ No. 80, 82, No. 143 90, 93, 94, 96, 97, 98 SEQ ID LTWEQAVK 226-233 for the proteins of SEQ No. 87, 89, No. 144 99, 101, 103, 105 SEQ ID LTWEQTVK 226-233 for the protein of SEQ No. 85 No. 145 SEQ ID LVAWFVGR 77-84 for the protein of SEQ No. 103 No. 146 SEQ ID LVNWFIEHGYR 77-87 for the protein of SEQ No. 88 No. 147 SEQ ID LVNWFVER 77-84 for the proteins of SEQ No. 83, 85, No. 148 86, 91, 92, 95, 99, 100, 101, 102, 104, 105 SEQ ID LVTWFVER 77-84 for the proteins of SEQ No. 80, 81, No. 149 82, 84, 87, 89, 90, 93, 94, 96, 97, 98 SEQ ID LVVPGHSEVGDASLLK 210-225 for the proteins of SEQ No. 93, 96, No. 150 97 SEQ ID LVVPSHSDIGDASLLK 210-225 for the proteins of SEQ No. 89, 99, No. 151 101 SEQ ID LVVPSHSDIGDSSLLK 210-225 for the protein of SEQ No. 85 No. 152 SEQ ID LVVPSHSDVGDASLLK 210-225 for the protein of SEQ No. 105 No. 153 SEQ ID LVVPSHSEAGDASLLK 210-225 for the proteins of SEQ No. 82, 94 No. 154 SEQ ID LVVPSHSEVGDASLLK 210-225 for the proteins of SEQ No. 80, 81, No. 155 84, 90, 98 SEQ ID LVVSGHSEIGNASLLK 210-225 for the protein of SEQ No. 103 No. 156 SEQ ID LVVSGHSETGDATHLK 210-225 for the protein of SEQ No. 95 No. 157 SEQ ID LVVSSHSDIGDVSLLK 210-225 for the protein of SEQ No. 86 No. 158 SEQ ID LVVSSHSEIGDASLLK 210-225 for the proteins of SEQ No. 83, 91, No. 159 92, 100, 102 SEQ ID LVVSSHSEIGNASLLQR 210-226 for the protein of SEQ No. 88 No. 160 SEQ ID LVVSSHSEK 210-218 for the protein of SEQ No. 104 No. 161 SEQ ID LVVSSHSETGNASLLK 210-225 for the protein of SEQ No. 87 No. 162 SEQ ID NDAYLIDTPITAK 60-72 for the proteins of SEQ No. 86, 88 No. 163 SEQ ID NSFDGVSYWLAK 134-145 for the protein of SEQ No. 95 No. 164 SEQ ID NSFGGVNYWLVK 134-145 for the proteins of SEQ No. 82, 94 No. 165 SEQ ID NSFSGASYWLVK 134-145 for the proteins of SEQ No. 81, 84 No. 166 SEQ ID NSFSGGSYWLVNNK 134-147 for the protein of SEQ No. 87 No. 167 SEQ ID NSFSGVSYWLLK 134-145 for the protein of SEQ No. 105 No. 168 SEQ ID NSFSGVSYWLVK 134-145 for the proteins of SEQ No. 83, 89, No. 169 91, 92, 99, 100, 101, 102, 103 SEQ ID SIPTYASELTNELLK 111-125 for the proteins of SEQ No. 80, 81, No. 170 82, 83, 84, 85, 86, 87, 90, 91, 92, 93, 94, 95, 96, 97, 98, 100, 102, 103, 104, 105 SEQ ID TLEQAVK 227-233 for the proteins of SEQ No. 80, 81, No. 171 82, 84, 90, 93, 94, 96, 97, 98 SEQ ID TWEQALK 227-233 for the protein of SEQ No. 104 No. 172 SEQ ID TWEQAVK 227-233 for the proteins of SEQ No. 83, 86, No. 173 87, 88, 89, 91, 92, 95, 99, 100, 101, 102, 103, 105 SEQ ID VLFGGCFVK 171-179 for the proteins of SEQ No. 81, 84, No. 174 85, 87 SEQ ID VQATNSFSGVNYWLVK 130-145 for the proteins of SEQ No. 80, 90, No. 175 93, 96, 97, 98 SEQ ID VQATNSFSGVSYSLIK 130-145 for the protein of SEQ No. 88 No. 176 SEQ ID VQATNSFSGVSYWLVK 130-145 for the protein of SEQ No. 103 No. 177 SEQ ID YGNAK 205-209 for the proteins of SEQ No. 89, 99, No. 178 101, 105 SEQ ID YSFSEVSYWLVK 134-145 for the protein of SEQ No. 104 No. 179 SEQ ID YSFSGVSYWLVK 134-145 for the protein of SEQ No. 85 No. 180

The detection of a mechanism of resistance to carbapenems induced by the expression of the IND protein is characterised by the detection of at least one peptide belonging to the IND protein and to its different sequence variants SEQ ID No. 181 to SEQ ID No. 187.

SEQ ID No. 181: MKKSIRFFIVSILLSPFASAQVKDFVIEPPIKNNLHIYKTFGVFGGKEYS ANSMYLVTKKGVVLFDVPWEKIQYQSLMDTIKKRHNLPVVAVFATHSHDD RAGDLSFFNNKGIKTYATAKTNEFLKKDGKATSTEIIKTGKPYRIGGEEF VVDFLGEGHTADNVVVWFPKYNVLDGGCLVKSNSATDLGYIKEANVEQWP KTINKLKAKYSKATLIIPGHDEWKGGGHVEHTLELLNKK SEQ ID No. 182: MKKSIQLLMMSMFLSPLINAQVKDFVIEPPVKPNLYLYKSFGVFGGKEYS ANAVYLTTKKGVVLFDVPWQKEQYQTLMDTIQKRHHLPVIAVFATHSHDD RAGDLSFYNQKGIKTYATAKTNELLKKDGKATSTEIIKTGKPYKIGGEEF MVDFLGEGHTVDNVVVWFPKYKVLDGGCLVKSRTATDLGYTGEANVKQWP ETMRKLKTKYAQATLVIPGHDEWKGGGHVQHTLDLLDKNKKPE SEQ ID No. 183: MKKSIQLLMMSMFLSPLINAQVKDFVIEPPVKPNLYLYKSFGVFGGKEYS ANAVYLTTKKGWLFDVPWQKEQYQTLMDTIQKRHHLPVIAVFATHSHDDR AGDLSFYNQKGIKTYATAKTNELLKKDGKATSTEIIKTGKPYKIGGEEFM VDFLGEGHTVDNVVVWFPKYKVLDGGCLVKSRTATDLGYTGEANVKQWPE TMRKLKTKYAQATLVIPGHEEWKGGGHVQHTLDLLDKNKKPE SEQ ID No. 184: MKKRIQFFMVSMMLSSLFSAQVKDFVIEPPIKKNLHIYKTFGVFGGKEYS ANSVYLVTQKGVVLFDVPWEKVQYQSLMDTIQKRHNLPVIAVFATHSHDD RAGDLSFFNNKGIKTYATSKTNEFLKKDGKATSTEIIKTGKPYRIGGEEF VVDFLGEGHTADNVVVWFPKYNVLDGGCLVKSKAATDLGYIKEANVEQWP KTINKLKSKYSKASLVIPGHDEWKGGGHVKHTLELLNKK SEQ ID No. 185: MRKNVRIFTVLSLFLINFFNAQARDFVIEQPFGKQLYLYKTFGVFDGKEY STNALYLVTKKGVVLFDVPWQKTQYQSLMDTIKKRHNLPVIAVFATHSHS DRAGDLSFYNKKGIPTYATAKTNELLKKEGKATSSKLTKIGKKYKIGGEE FTVDFLGEGHTADNVVVWFPKYNVLDGGCLVKSSAAVDLGYTGEANVEQW PATMKKLQAKYPSTAKVIPGHDEWKGNDHVKHTLELLDQQKQ SEQ ID No. 186: MKKRIQFFMVSMMLAPMFNAQVKDFVIEPPIKNNLHIYKTFGVFGGKEYS ANSVYLVTKKGVVLFDVPWEKAQYQSLMDTIKKRHNLPVIAVFATHSHDD RAGDLSFFNNKGIKTYATSKTNEFLKKDGKATSTEIIKTGKPYRIGGEEF TVDFLGEGHTADNVVVVVFPKYNVLDGGCLVKSNSATDLGYIKEANVEQW PITIDKLKAKYSKATLIIPGHDDWKGGGHVEHTLELLNKK SEQ ID No. 187: MKRRIQFFMVSMMLTPLFSAQVKDFVIEPPIKKNLYIYKTFGVFGGKEYS ANSVYLVTKTGVVLFDVPWEKAQYQSLMDTIKKRHNLPVVAVFATHSHDD RAGDLSFFNNKGIKTYATPKTNQFLKRDGKATSTELIKPGKPYRFGGEEF VVDFLGEGHTADNVVVWFPKYKVLDGGCLVKSNSATDLGYIKEANLEQWP KTMHKLKTKYSEAVLIIPGHDEWKGGGHVEHTLELLDKK

said peptides being chosen, preferably, from the peptides of sequence SEQ ID No. 188 to SEQ ID No. 197, SEQ ID No. 200, SEQ ID No. 201, SEQ ID No. 203 to SEQ ID No. 262, as defined hereafter:

Peptide SEQ ID No. Amino acid sequence Position of the peptide in the IND protein(s) SEQ ID AATDLGYIK 184-192 for the protein of SEQ No. 184 No. 188 SEQ ID AGDLSFFNNK 102-111 for the proteins of SEQ No. 181, 184, 186, No. 189 187 SEQ ID AGDLSFYNK 103-111 for the protein of SEQ No. 185 No. 190 SEQ ID AGDLSFYNQK 102-111 for the proteins of SEQ No. 182, 183 No. 191 SEQ ID AQYQSLMDTIK 72-82 for the proteins of SEQ No. 186, 187 No. 192 SEQ ID ASLVIPGHDEWK 213-224 for the protein of SEQ No. 184 No. 193 SEQ ID ATLIIPGHDDWK 213-224 for the protein of SEQ No. 186 No. 194 SEQ ID ATLIIPGHDEWK 213-224 for the protein of SEQ No. 181 No. 195 SEQ ID ATSSK 132-136 for the protein of SEQ No. 185 No. 196 SEQ ID ATSTEIIK 131-138 for the proteins of SEQ No. 181, 182, 183, No. 197 184, 186 SEQ ID ATSTELIK 131-138 for the protein of SEQ No. 187 No. 198 SEQ ID ATSTELIKPGK 131-141 for the protein of SEQ No. 187 No. 199 SEQ ID ATSTELIKPGKPYR 131-144 for the protein of SEQ No. 187 No. 200 SEQ ID DFVIEPPIK 24-32 for the proteins of SEQ No. 181, 184, 186, 187 No. 201 SEQ ID DFVIEPPVK 24-32 for the proteins of SEQ No. 182, 183 No. 202 SEQ ID DFVIEPPVKPNLYLYK 24-39 for the proteins of SEQ No. 182, 183 No. 203 SEQ ID DFVIEQPFGK 25-34 for the protein of SEQ No. 185 No. 204 SEQ ID EANLEQWPK 193-201 for the protein of SEQ No. 187 No. 205 SEQ ID EANVEQWPITIDK 193-205 for the protein of SEQ No. 186 No. 206 SEQ ID EANVEQWPK 193-201 for the proteins of SEQ No. 181, 184 No. 207 SEQ ID EQYQTLMDTIQK 72-83 for the proteins of SEQ No. 182, 183 No. 208 SEQ ID EYSANAVYLTTK 48-59 for the proteins of SEQ No. 182, 183 No. 209 SEQ ID EYSANSMYLVTK 48-59 for the protein of SEQ No. 181 No. 210 SEQ ID EYSANSVYLVTK 48-59 for the proteins of SEQ No. 186, 187 No. 211 SEQ ID EYSANSVYLVTQK 48-60 for the protein of SEQ No. 184 No. 212 SEQ ID EYSTNALYLVTK 49-60 for the protein of SEQ No. 185 No. 213 SEQ ID FFIVSILLSPFASAQVK 7-23 for the protein of SEQ No. 181 No. 214 SEQ ID GGGHVEHTLELLDK 225-238 for the protein of SEQ No. 187 No. 215 SEQ ID GGGHVEHTLELLNK 225-238 for the proteins of SEQ No. 181, 186 No. 216 SEQ ID GGGHVK 225-230 for the protein of SEQ No. 184 No. 217 SEQ ID GGGHVQHTLDLLDK 225-238 for the proteins of SEQ No. 182, 183 No. 218 SEQ ID GIPTYATAK 113-121 for the protein of SEQ No. 185 No. 219 SEQ ID GNDHVK 226-231 for the protein of SEQ No. 185 No. 220 SEQ ID GVVLFDVPWEK 61-71 for the proteins of SEQ No. 181, 184, 186, 187 No. 221 SEQ ID GVVLFDVPWQK 62-72 for the protein of SEQ No. 185; 61-71 for the No. 222 protein of sequence SEQ ID No. 182; 61-71 for the protein of sequence SEQ ID No. 183 SEQ ID HHLPVIAVFATHSHDDR 85-101 for the proteins of SEQ No. 182, 183 No. 223 SEQ ID HNLPVIAVFATHSHDDR 85-101 for the proteins of SEQ No. 184, 186 No. 224 SEQ ID HNLPVIAVFATHSHSDR 86-102 for the protein of SEQ No. 185 No. 225 SEQ ID HNLPVVAVFATHSHDDR 85-101 for the proteins of SEQ No. 181, 187 No. 226 SEQ ID HTLELLDQQK 232-241 for the protein of SEQ No. 185 No. 227 SEQ ID HTLELLNK 231-238 for the proteins of SEQ No. 181, 184, 186 No. 228 SEQ ID IFTVLSLFLINFFNAQAR 7-24 for the protein of SEQ No. 185 No. 229 SEQ ID IQFFMVSMMLAPMFNAQVK 5-23 for the protein of SEQ No. 186 No. 230 SEQ ID IQFFMVSMMLSSLFSAQVK 5-23 for the protein of SEQ No. 184 No. 231 SEQ ID IQFFMVSMMLTPLFSAQVK 5-23 for the protein of SEQ No. 187 No. 232 SEQ ID IQYQSLMDTIK 72-82 for the protein of SEQ No. 181 No. 233 SEQ ID NLHIYK 34-39 for the proteins of SEQ No. 181, 184, 186 No. 234 SEQ ID NLYIYK 34-39 for the protein of SEQ No. 187 No. 235 SEQ ID NNLHIYK 33-39 for the proteins of SEQ No. 181, 186 No. 236 SEQ ID QLYLYK 35-40 for the protein of SEQ No. 185 No. 237 SEQ ID QWPETMR 198-204 for the proteins of SEQ No. 182, 183 No. 238 SEQ ID SFGVFGGK 40-47 for the proteins of SEQ No. 182, 183 No. 239 SEQ ID SIQLLMMSMFLSPLINAQVK 4-23 for the proteins of SEQ No. 182, 183 No. 240 SEQ ID SNSATDLGYIK 182-192 for the proteins of SEQ No. 181, 186, 187 No. 241 SEQ ID TATDLGYTGEANVK 184-197 for the proteins of SEQ No. 182, 183 No. 242 SEQ ID TFGVFDGK 41-48 for the protein of SEQ No. 185 No. 243 SEQ ID TFGVFGGK 40-47 for the proteins of SEQ No. 181, 184, 186, 187 No. 244 SEQ ID TGKPYK 139-144 for the proteins of SEQ No. 182, 183 No. 245 SEQ ID TGKPYR 139-144 for the proteins of SEQ No. 181, 184, 186 No. 246 SEQ ID TGVVLFDVPWEK 60-71 for the protein of SEQ No. 187 No. 247 SEQ ID TNEFLK 121-126 for the proteins of SEQ No. 181, 184, 186 No. 248 SEQ ID TNELLK 122-127 for the protein of SEQ No. 185; 121-126 for No. 249 the proteins of sequence SEQ ID No. 182, 183 SEQ ID TNQFLK 121-126 for the protein of SEQ No. 187 No. 250 SEQ ID TQYQSLMDTIK 73-83 for the protein of SEQ No. 185 No. 251 SEQ ID TYATAK 116-121 for the protein of SEQ No. 185; 115-120 for No. 252 the proteins of sequence SEQ ID No. 181, 182, 183 SEQ ID TYATPK 115-120 for the protein of SEQ No. 187 No. 253 SEQ ID TYATSK 115-120 for the proteins of SEQ No. 184, 186 No. 254 SEQ ID VIPGHDEWK 217-225 for the protein of SEQ No. 185; 216-224 for No. 255 the protein of sequence SEQ ID No. 182; 216-224 for the protein of sequence SEQ ID No. 184 SEQ ID VLDGGCLVK 173-181 for the proteins of SEQ No. 181, 182, 183, No. 256 184, 186, 187; 174-182 for the protein of sequence SEQ ID No. 185 SEQ ID VQYQSLMDTIQK 72-83 for the protein of SEQ No. 184 No. 257 SEQ ID YAQATLVIPGHDEWK 210-224 for the protein of SEQ No. 182 No. 258 SEQ ID YAQATLVIPGHEEWK 210-224 for the protein of SEQ No. 183 No. 259 SEQ ID YNVLDGGCLVK 171-181 for the proteins of SEQ No. 181, 184, 186; No. 260 172-182 for the protein of sequence SEQ ID No. 185 SEQ ID YPSTAK 211-216 for the protein of SEQ No. 185 No. 261 SEQ ID YSEAVLIIPGHDEWK 210-224 for the protein of SEQ No. 187 No. 262

The detection of a mechanism of resistance to carbapenems induced by the expression of the SME protein is characterised by the detection of at least one peptide belonging to the SME protein and to its different sequence variants SEQ ID No. 263 to SEQ ID No. 265.

SEQ ID No. 263: MSNKVNFKTASFLFSVCLALSAFNAHANKSDAAAKQIKKLEEDFDGRIGV FAIDIGSGNIFGYRSDERFPLCSSFKGFLAAAVLERVQQKKLDINQKVKY ESRDLEYHSPITTKYKGSGMTLGDMASAALQYSDNGATNIIMERFLGGPE GMTKFMRSIGDNEFRLDRWELELNTAIPGDKRDTSTPKAVANSLNKLALG NVLNAKEKAIYQNWLKGNITGDARIRASVPADVVVVGDKTGSCGAYGTAN DYAVIWPKNRAPLIVSIYTTRKSKDDKHSDKTIAEASRIAIQAID SEQ ID No. 264: MSNKVNFKTASFLFSVCLALSAFNAHANKSDAAAKQIKKLEEDFDGRIGV FAIDTGSGNTFGYRSDERFPLCSSFKGFLAAAVLERVQQKKLDINQKVKY ESRDLEYYSPITTKYKGSGMTLGDMASAALQYSDNGATNIIMERFLGGPE GMTKFMRSIGDNEFRLDRWELELNTAIPGDKRDTSTPKAVANSLNKLALG NVLNAKVKAIYQNWLKGNTTGDARIRASVPADWVVGDKTGSCGAYGTAND YAVIWPKNRAPLIVSIYTTRKSKDDKHSDKTIAEASRIAIQAID SEQ ID No. 265: MSNKVNFKTASFLFSVCLALSAFNAHANKSDAAAKQIKKLEEDFDGRIGV FAIDTGSGNTFGYRSDERFPLCSSFKGFLAAAVLERVQQKKLDINQKVKY ESRDLEYHSPITTKYKGSGMTLGDMASAALQYSDNGATNIIMERFLGGPE GMTKFMRSIGDNEFRLDRWELELNTAIPGDKRDTSTPKAVANSLNKLALG NVLNAKVKAIYQNWLKGNTTGDARIRASVPADVINVGDKTGSCGAIGTAN DYAVIWPKNRAPLIVSIYTTRKSKDDKHSDKTIAEASRIAIQAID

said peptides being chosen, preferably, from the peptides of sequence SEQ ID No. 266 to SEQ ID No. 287 as defined hereafter:

Peptide SEQ ID Position of the peptide in the SME No. Amino acid sequence protein(s) SEQ ID AIYQNWLK 209-216 for the proteins of SEQ No. 263, No. 266 264, 265 SEQ ID APLIVSIYTTR 260-270 for the proteins of SEQ No. 263, No. 267 264, 265 SEQ ID ASVPADWVVGDK 227-238 for the proteins of SEQ No. 263, No. 268 264, 265 SEQ ID AVANSLNK 189-196 for the proteins of SEQ No. 263, No. 269 264, 265 SEQ ID DLEYHSPITTK 104-114 for the proteins of SEQ No. 263, No. 270 265 SEQ ID DLEYYSPITTK 104-114 for the protein of SEQ No. 264 No. 271 SEQ ID DTSTPK 183-188 for the proteins of SEQ No. 263, No. 272 264, 265 SEQ ID FLGGPEGMTK 145-154 for the proteins of SEQ No. 263, No. 273 264, 265 SEQ ID GFLAAAVLER 77-86 for the proteins of SEQ No. 263, No. 274 264, 265 SEQ ID GNTTGDAR 217-224 for the proteins of SEQ No. 263, No. 275 264, 265 SEQ ID IGVFAIDTGSGNTFGYR 48-64 for the proteins of SEQ No. 263, No. 276 264, 265 SEQ ID LALGNVLNAK 197-206 for the proteins of SEQ No. 263, No. 277 264, 265 SEQ ID LDINQK 92-97 for the proteins of SEQ No. 263, No. 278 264, 265 SEQ ID LEEDFDGR 40-47 for the proteins of SEQ No. 263, No. 279 264, 265 SEQ ID SDAAAK 30-35 for the proteins of SEQ No. 263, No. 280 264, 265 SEQ ID SIGDNEFR 158-165 for the proteins of SEQ No. 263, No. 281 264, 265 SEQ ID TASFLFSVCLALSAFNAHANK 9-29 for the proteins of SEQ No. 263, 264, No. 282 265 SEQ ID TGSCGAIGTANDYAVIWPK 239-257 for the protein of SEQ No. 265 No. 283 SEQ ID TGSCGAYGTANDYAVIWPK 239-257 for the proteins of SEQ No. 263, No. 284 264 SEQ ID TIAEASR 281-287 for the proteins of SEQ No. 263, No. 285 264, 265 SEQ ID WELELNTAIPGDK 169-181 for the proteins of SEQ No. 263, No. 286 264, 265 SEQ ID FPLCSSFK 69-76 for the proteins of SEQ No. 263, No. 287 264, 265

The detection of a mechanism of resistance to carbapenems induced by the expression of a VIM protein is characterised by the detection of at least one peptide belonging to a VIM protein and to its different sequence variants SEQ ID No. 288 to SEQ ID No. 313.

SEQ ID No. 288: MFKLLSKLLVYLTASIMAIASPLAFSVDSSGEYPTVSEIPVGEVRLYQIA DGVVVSHIATQSFDGAVYPSNGLIVRDGDELLLIDTAWGAKNTAALLAEI EKQIGLPVTRAVSTHFHDDRVGGVDVLRAAGVATYASPSTRRLAEVEGNE lPTHSLEGLSSSGDAVRFGPVELFYPGAAHSTDNLVVYVPSASVLYGGCA IYELSRTSAGNVADADLAEWPTSIERIQQHYPEAQFVIPGHGLPGGLDLL KHTTNVVKAHTNRSVVE SEQ ID No. 289: MFKLLSKLLVYLTASIMAIASPLAFSVDSSGEYPTVSEIPVGEVRLYQIA DGVVVSHIATKSFDGAVYPSNGLIVRDGDELLLIDTAWGAKNTAALLAEI EKQIGLPVTRAVSTHFHDDRVGGVDVLRAAGVATYASPSTRRLAEVEGSE IPTHSLEGLSSSGDAVRFGPVELFYPGAAHSTDNLVVYVPSASVLYGGCA IYELSRTSAGNVADADLAEWPTSIERIQQHYPEAQFVIPGHGLPGGLDLL KHTTNVVKAHTNRSVVE SEQ ID No. 290: MLKVISSLLVYMTASVMAVASPLAHSGEPSGEYPTVNElPVGEVRLYQIA DGVVVSHIATQSFDGAVYPSNGLIVRDGDELLLIDTAWGAKNTAALLAEI EKQIGLPVTRAVSTHFHDDRVGGVDVLRAAGVATYASPSTRRLAEAEGNE IPTHSLEGLSSSGDAVRFGPVELFYPGAAHSTDNLVVYVPSANVLYGGCA VHELSRTSAGNVADADLAEWPTSVERIQKHYPEAEWIPGHGLPGGLDLLQ HTANVVKAHKNRSVAE SEQ ID No. 291: MLKVISSLLVYMTASVMAVASPLAHSGEPSGEYPTVNElPVGEVRLYQIA DGVWSHIATQSFDGAVYPSNGLIVRDGDELLLIDTAWGAKNTAALLAEIE KQIGLPVTRAVSTHFHDDRVGGVDVLRKAGVATYASPSTRRLAEAEGNE1 PTHSLEGLSSSGDAVRFGPVELFYPGAAHSTDNLVVYVPSANVLYGGCAV LALSRTSAGNVADADLAEWPTSVERIOKHYPEAEWIPGHGLPGGLDLLQH TANVVTAHKNRSVAE SEQ ID No. 292: MFKLLSKLLVYLTASIMAIASPLAFSVDSSGEYPTVSEIPVGEVRLYQIA DGVWSHIATRSFDGAVYPSNGLIVRDGDELLLIDTAWGAKNTAALLAEIE KQIGLPVTRAVSTHFHDDRVGGVDVLRAAGVATYASPSTRRLAEVEGSEI PTHSLEGLSSSGDAVRFGPVELFYPGAAHSTDNLVVYVPSASVLYGGCAI YELSRTSAGNVADADLAEWPTSIERIQQHYPEAQFVIPGHGLPGGLDLLK HTTNVVKAHTNRSVVE SEQ ID No. 293: MFKLLSKLLVYLTASIMAIASPLAFSVDSSGEYPTVSEIPVGEVRLYQIA DGVWSHIATQSFDGAVYPSNGLIVRDGDELLLIDTAWGAKNTAALLAEIE KQIGLPVTRAVSTHFHDDRVGGVDVLRAAGVATYASPSARRLAEVEGNEI PTHSLEGLSSSGDAVRFGPVELFYPGAAHSTDNLVVYVPSASVLYGGCA1 YELSRTSAGNVADADLAEWPTSIERIQQHYPEAQFVIPGHGLPGGLDLLK HTTNVVKAHTNRSVVE SEQ ID No. 294: MFKLLSKLLVYLTASIMAIASPLAFSVDSSGEYPTVSEIPVGEVRLYQ1A DGVVVSHIATQSFDGAVYPSNGL1VRDGDELLLIDTAWGAKNTAALLAEI EKQIGLPVTRAVSTHFHDDRVGGVDVLRAAGVATYASPSIRRLAEVEGNE IPTHSLEGLSSSGDAVRFGPVELFYPGAAHSTDNLVVYVPSASVLYGGCA IYELSRTSAGNVADADLAEWPTSIERIQQHYPEAQFVIPGHGLPGGLDLL KHTTNVVKAHTNRSVVE SEQ ID No. 296: MFKLLSKLLVYLTASIMAIASPLAFSVDSSGEYPTVSEIPVGEVRLYQIA DGVVVSHIATQSFDGAVYPSNGLIVRDGDELLLIDTAWGAKNTAALLAEI EKQIGLPVTRAVSTHFHDDRVGGVDVLRAAGVATYASPSTRRLAEVEGNE lPTHSLEGLSSSGDAVRFGPVELFYPGAAHSTDNLVVYVPSASVLYGGCA IYELSRTSAGNVADADLAEWPTSIER1QQHYPEAQYVIPGHGLPGGLDLL KHTTNWKAHTNRSVVE SEQ ID No. 296: MFKLLSKLLVYLTASIMAIASPLAFSVDSSGEYPTVSEIPVGEVRLYQIA DGVWSH1ATQSFDGAVYPSNGLIVRDGDELLLIDTAWGAKNTAALLAEIE KQIGLPVTRAVSTHFHDDRVGGVDVLRAAGVATYASPSTRRLAEVEGSEI PTHSLEGLSSSGDAVRFGPVELFYPGAAHSTDNLVVYVPSASVLYGGCAI YELSRTSAGNVADADLAEWPTSIERIQQHYPEAQFVIPGHGLPGGLDLLK HTTNVVKAHTNRSVVE SEQ ID No. 297: MLKVISSLLVYMTASVMAVASPLAHSGEPSSEYPTVNElPVGEVRLYQIA DGVVVSHIATQSFDGAVYPSNGLIVRDGDELLLIDTAWGAKNTAALLAEI EKQIGLPVTRAVSTHFHDDRVGGVDVLRAAGVATYASPSTRRLAEAEGNE IPTHSLEGLSSSGDAVRFGPVELFYPGAAHSTDNLVVYVPSANVLYGGCA VHELSRTSAGNVADADLAEWPTSVERIOKHYPEAEVVIPGHGLPGGLDLL QHTANVVKAHKNRSVAE SEQ ID No. 298: MLKVISSLLVYMTASVMAVASPLAHSGEPSGEYPTVNElPVGEVRLYQIA DGV1NSHIATQSFDGAVYPSNGLIVRDGDELLLIDTAWGAKNTAALLAEI EKQIGLPVTRAVSTHFHDDRVGGVDVLRAAGVATYASPSTRRLAEAEGNE lPTHSLEGLSSSGDAVRFGPVELFYPGAAHSTDNLWYVPSANVLYGGCAV HELSSTSAGNVADADLAEWPTSIERIQQHYPEAQFVIPGHGLPGGLDLLK HTTNVVKAHTNRSVVE SEQ ID No. 299: MLKVISSLLFYMTASLMAVASPLAHSGESRGEYPTVSEIPVGEVRLYQID DGVVVSHIATHTFDGVVYPSNGLIVRDGDELWDTAWGTKNTVALLAEIEK QIGLPVTRSVSTHFHDDRVGGVDALRAAGVATYASPSTRRLAEAEGNEVP THSLEGLSSSGDAVRFGPVELFYPGAAHSTDNLVVYVPSANVLYGGCAVL ELSRTSAGNVADADLAEWPGSVERIQQHYPEAEVVIPGHGLPGGLDLLQH TANVVKAHTNRSVAE SEQ ID No. 300: MFKLLSKLLVYLTASMMAIASPLAFSVDSSGEYPTVSEIPVGEVRLYQIA DGVWSHIATQSFDGAVYPSNGLIVRDGDELLLIDTAWGAKNTAALLAEIE KQ1GLPVTRAVSTHFHDDRVGGVDVLRAAGVATYASPSTRRLAEVEGNEl PTHSLEGLSSSGDAVRFGPVELFYPGAAHSTDNLVVYVPSASVLYGGCA1 YELSRTSAGNVADADLAEWPTSIERIQQHYPEAQFVIPGHGLPGGLDLLK HTTNVVKAHTNRSVVE SEQ ID No. 301: MFKLLSKLLVYLTASIMAIASPLAFSVDSSGEYPTVSEIPVGEVRLYQIA DGVWSHIATQSFDGAVYPSNGLIVRDGDELLL1DTAWGAKNTAALLAEIE KQIGLPVTRAVSTHFHDDRVGGVDVLRAAGVATYASPSTRRLAEVEGNEI PTHSLEGLSSSGDAVRFGPVELFYPGAAHSTDNLVVYVPSASVLFGGCAI YELSRTSAGNVADADLAEWPTSIERIQQHYPEAQFVIPGHGLPGGLDLLK HTTNVVKAHTNRSVVE SEQ ID No. 302: MFKLLSKLLVYLTASIMAIASPLAFSVDSSGEYPTVSEIPVGEVRLYQIA DGVWLHIATQSFDGAVYPSNGLIVRDGDELLLIDTAWGAKNTAALLAEIE KQ1GLPVTRAVSTHFHDDRVGGVDVLRAAGVATYASPSTRRLAEVEGNEl PTHSLEGLSSSGDAVRFGPVELFYPGAAHSTDNLVVYVPSASVLYGGCAI YELSRTSAGNVADADLAEWPTSIERIQQHYPEAQFVIPGHGLPGGLDLLK HTTNVVKAHTNRSVVE SEQ ID No. 303: MFKLLSKLLVYLTASIMAIASPLAFSVDSSGEYPTVSEIPVGEVRLYQIA DGVWSHIATQSFDGAVYPSNGLIVRDGDELLLIDTAWGAKNTAALLAEIE KQIGLPVTRAVSTHFHDDRVGGVDVLRAAGVATYASPSTRRLAEVEGNEl PTHSLEGLSSSGDAVRFGPVELFYPGAAHSTDNLVVYVPSASVLYGGCAI YELSSTSAGNVADADLAEWPTS1ERIQQHYPEAQFVIPGHGLPGGLDLLK HTTNVVKAHTNRSVVE SEQ ID No. 304: MLKVISSLLVYMTASVMAVASPLAHSGEPSGEYPTVNEIPVGEVRLYQ1A DGVWSHIATQSFDGAVYPSNGLIVRDGDELLLIDTAWGAKNTAALLAEIE KQIGLPVTRAVSTHFHDDRVGGVDVLRAAGVATYASPSTRRLAEAEGNEl PTHSLEGLSSSGDAVRFGPVELFYPGAAHSTDNLVVYVPSAKVLYGGCAV HELSRTSAGNVADADLAEWPTSVERIQKHYPEAEVVIPGHGLPGGLDLLQ HTANVVKAHKNRSVAE SEQ ID No. 305: MFKLLSKLLVYLTAS1MAIASPLAFSVDSSGEYPTVSEIPVGEVRLYQIA DGVWSHIATQSFDGAVYPSNGLIVRDGDELLLIDTAWGAKNTAALLAEIE KQIGLPVTRAVSTHFHDDRVGGVDVLRAAGVATYASPSTRRLAEVEGNEI PTHSLEGLSSSGDAVRFGPVELFYPGAAHSTDNLVVYVPSASVLYGGCAI YELSLTSAGNVADADLAEWPTSIERIQQHYPEAQFVIPGHGLPGGLDLLK HTTNWKAHTNRSWE SEQ ID No. 306: MLKVISSLLVYMTASVMAVASPLAHSGEPSGEYPTVNEIPVGEVRLYQIA DGVWSHIATQSFDGAVYPSNGLIVRDGDELLLIDTAWGAKNTAALLAEIE KQIGLPVTRAVSTHFHDDRVGGVDVLRKAGVATYASPSTRRLAEAEGNEI PTHSLEGLSSSGDAVRFGPVELFYPGAAHSTDNLVVYVPSANVLYGGCAV LALSRTSAGNVADADLAEWPTSVERIQKHYPEAQFVIPGHGLPGGLDLLK HTTNVVKAHTNRSVVE SEQ ID No. 307: MLKVISSLLVYMTASVMAVASPLAHSGEPSGEYPTVNElPVGEVRLYQIA DGVWSHISTQSFDGAVYPSNGLIVRDGDELLLIDTAWGAKNTAALLAEIE KQIGLPVTRAVSTHFHDDRVGGVDVLRAAGVATYASPSTRRLAEAEGNEl PTHSLEGLSSSGDAVRFGPVELFYPGAAHSTDNLVVYVPSANVLYGGCAV HELSSTSAGNVADADLAEWPTSVERIQKHYPEAEVVIPGHGLPGGLDLLQ HTANVVKAHKNRSVAE SEQ ID No. 308: MLKVISSLLVYMTASVMAVASPLAHSGEPSGEYPTVNElPVGEVRLYQIA DGVVVSHIATQSFDGAVYPSNGLIVRDGDELLLIDTAWGAKNTAALLAEI EKQIGLPVTRAVSTHFHDDRVGGVDVLRAAGVATYASPSTRRLAEAEGNE IPTHSLEGLSSSGDAVRFGPVELFYPGAAHSTDNLVVYVPSANVLYGGCA VLELSRTSAGNVADADLAEWPTSVER1QKHYPEAEVVIPGHGLPGGLDLL QHTANVVKAHKNRSVAE SEQ ID No. 309: MFKLLSKLLVYLTASIMAIASPLAFSVDSSGEYPTVNEIPVGEVRLYQIA DGVWSHIATQSFDGAVYPSNGLIVRDGDELLLIDTAWGAKNTAALLAEIE KQIGLPVTRAVSTHFHDDRVGGVDVLRAAGVATYASPSTRRLAEVEGNEI PTHSLEGLSSSGDAVRFGPVELFYPGAAHSTDNLVVYVPSASVLYGGCAI YELSRTSAGNVADADLAEWPTSIERIQQHYPEAQFVIPGHGLPGGLDLLK HTTNVVKAHTNRSVVE SEQ ID No. 310: MLKVISSLLVYMTASVMAVASPLAHSGEPSGEYPTVNEIPVGEVRLYQ1A DGVVVSHIATQSFDGAVYPSNGLIVRDGDELLLIDTAWGAKNTAALLAEI EKQIGLPVTRAVSTHFHDDRVGGVDVLRAAGVATYASPSTRRLAEAEGNE IPTHSLEGLSSSGDAVRFGPVELFYPGAAHSTDNLVVYVPSANVLYGGCA VHELSSTSAGNVADADLAEWPTSVERIQKHYPEAEVVIPGHGLPGGLDLL QHTANVVKAHKNRSVAE SEQ ID No. 311: MFQIRSFLVGISAFVMAVLGSAAYSAQPGGEYPTVDDIPVGEVRLYKIGD GVVVSHIATQKLGDTVYSSNGLIVRDADELLLIDTAWGAKNTVALLAEIE KQIGLPVTRSISTHFHDDRVGGVDVLRAAGVATYTSPLTRQLAEAAGNEV PAHSLKALSSSGDVVRFGPVEVFYPGAAHSGDNLVVYVPAVRVLFGGCAV HEASRESAGNVADANLAEWPATIKRIQQRYPEAEVVIPGHGLPGGLELLQ HTTNWKTHKVRPVAE SEQ ID No. 312: MFKLLSKLLVYLTASIMAIASPLAFSVDSSGEYPTVSEIPVGEVRLYQIA DGVWSHIATRSFDGAVYPSNGLIVRDGDELLLIDTAWGAKNTAALLAEIE KQIGLPVTRAVSTHFHDDRVGGVDVLRAAGVATYASPSTRRLANEIPTHS LEGLSSSGDAVRFGPVELFYPGAAHSTDNLVVYVPSASVLYGGCAIYELS RTSAGNVADADLAEWPTSIERIQQHYPEAQFVIPGHGLPGGLDLLKHTTN VVKAHTNRSVVE SEQ ID No. 313: MLKVISSLLVYMTASVMAVASPLAHSGEPSGEYPTVNEIPVGEVRLYQIA DGVVVSHIATQSFDGAVYPSNGLIVRDGDELLLIDTAWGAKNTAALLAEI EKQIGLPVTRAVSTHFHDDRVGGVDVLRAAGVATYASPSTRRLAEAEGNE IPTHSLEGLSSSGDAVRFGPVELFYPGAAHSTDNLVVYVPSANVLYGGCA VLELSSTSAGNVADADLAEWPTSVERIQKHYPEAEVVIPGHGLPGGLDLL QHTANVVKAHKNRSVAE

said peptides being chosen, preferably, from the peptides of sequence SEQ ID No. 314 to SEQ ID No. 346 as defined hereafter:

Peptide SEQ ID No. Amino acid sequence Position of the peptide in the VIM protein(s) SEQ ID AAGVATYASPSAR 128-140 for the protein of SEQ No. 293 No. 314 SEQ ID AAGVATYASPSIR 128-140 for the protein of SEQ No. 294 No. 315 SEQ ID AAGVATYASPSTR 128-140 for the proteins of SEQ No. 288, 289, No. 316 290, 292, 295, 296, 297, 298, 299, 300, 301, 302, 303, 304, 305, 307, 308, 309, 310, 312, 313 SEQ ID AAGVATYTSPLTR 127-139 for the protein of SEQ No. 311 No. 317 SEQ ID AGVATYASPSTR 129-140 for the proteins of SEQ No. 288, 289, No. 318 290, 291, 292, 295, 296, 297, 298, 299, 300, 301, 302, 303, 304, 305, 306, 307, 308, 309, 310, 312, 313 SEQ ID AHTNR 254-258 for the protein of SEQ No. 312; 258-262 No. 319 for the proteins of sequence SEQ ID No. 288, 289, 292, 293, 294, 295, 296, 298, 299, 300, 301, 302, 303, 305, 306, 309 SEQ ID ALSSSGDVVR 156-165 for the protein of SEQ No. 311 No. 320 SEQ ID AVSTHFHDDR 110-119 for the proteins of SEQ No. 288, 289, No. 321 290, 291, 292, 293, 294, 295, 296, 297, 298, 300, 301, 302, 303, 304, 305, 306, 307, 308, 309, 310, 312, 313 SEQ ID DADELLLIDTAWGAK 75-89 for the protein of SEQ No. 311 No. 322 SEQ ID DGDELLLIDTAWGAK 76-90 for the proteins of SEQ No. 288, 289, 290, No. 323 291, 292, 293, 294, 295, 296, 297, 298, 300, 301, 302, 303, 304, 305, 306, 307, 308, 309, 310, 312, 313 SEQ ID DGDELLLIDTAWGTK 76-90 for the protein of SEQ No. 299 No. 324 SEQ ID ESAGNVADANLAEWPATIK 205-223 for the protein of SEQ No. 311 No. 325 SEQ ID GEYPTVSEIPVGEVR 31-45 for the proteins of SEQ No. 288, 289, 292, No. 326 293, 294, 295, 296, 299, 300, 301, 302, 303, 305, 312 SEQ ID HTTNVVK 247-253 for the protein of SEQ No. 312; 251-257 No. 327 for the proteins of sequence SEQ ID No. 288, 289, 292, 293, 294, 295, 296, 298, 300, 301, 302, 303, 305, 306, 309; 250-256 for the protein of sequence SEQ ID No. 311 SEQ ID IGDGVWSHIATQK 48-60 for the protein of SEQ No. 311 No. 328 SEQ ID LANEIPTHSLEGLSSSGDAVR 142-162 for the protein of SEQ No. 312 No. 329 SEQ ID LGDTVYSSNGLIVR 61-74 for the protein of SEQ No. 311 No. 330 SEQ ID LYQIADGVWSHIATK 46-60 for the protein of SEQ No. 289 No. 331 SEQ ID LYQIADGVWSHIATR 46-60 for the proteins of SEQ No. 292, 312 No. 332 SEQ ID NTAALLAEIEK 91-101 for the proteins of SEQ No. 288, 289, No. 333 290, 291, 292, 293, 294, 295, 296, 297, 298, 300, 301, 302, 303, 304, 305, 306, 307, 308, 309, 310, 312, 313 SEQ ID NTVALLAEIEK 90-100 for the protein of SEQ No. 311; 91-101 No. 334 for the protein of sequence SEQ ID No. 299 SEQ ID QIGLPVTR 102-109 for the proteins of SEQ No. 288, 289, No. 335 290, 291, 292, 293, 294, 295, 296, 297, 298, 299, 300, 301, 302, 303, 304, 305, 306, 307, 308, 309, 310, 312, 313; 101-108 for the protein of sequence SEQ ID No. 311 SEQ ID QLAEAAGNEVPAHSLK 140-155 for the protein of SEQ No. 311 No. 336 SEQ ID SFDGAVYPSNGLIVR 61-75 for the proteins of SEQ No. 288, 289, 290, No. 337 291, 292, 293, 294, 295, 296, 297, 298, 300, 301, 302, 303, 304, 305, 306, 307, 308, 309, 310, 312, 313 SEQ ID SISTHFHDDR 109-118 for the protein of SEQ No. 311 No. 338 SEQ ID SVSTHFHDDR 110-119 for the protein of SEQ No. 299 No. 339 SEQ ID TSAGNVADADLAEWPGSVER 206-225 for the protein of SEQ No. 299 No. 340 SEQ ID TSAGNVADADLAEWPTSIER 202-221 for the protein of SEQ No. 312; 206-225 No. 341 for the protein of sequence SEQ ID No. 288, 289, 292, 293, 294, 295, 296, 298, 300, 301, 302, 303, 305, 309 SEQ ID TSAGNVADADLAEWPTSVER 206-225 for the proteins of SEQ No. 290, 291, No. 342 297, 304, 306, 307, 308, 310, 313 SEQ ID VGGVDALR 120-127 for the protein of SEQ No. 299 No. 343 SEQ ID VGGVDVLR 120-127 for the proteins of SEQ No. 288, 289, No. 344 290, 291, 292, 293, 294, 295, 296, 297, 298, 300, 301, 302, 303, 304, 305, 306, 307, 308, 309, 310, 312, 313; 119-126 for the protein of sequence SEQ ID No. 311 SEQ ID VLFGGCAVHEASR 192-204 for the protein of SEQ No. 311 No. 345 SEQ ID VLYGGCAVHELSR 193-205 for the proteins of SEQ No. 290, 297, No. 346 304

The detection of a mechanism of resistance to carbapenems and/or to cephalosporins induced by the expression of an OXA protein is characterised by the detection of at least one peptide belonging to an OXA protein and to its different sequence variants SEQ ID No. 347 to SEQ ID No. 508.

SEQ ID No. 347: MSRLLLSGLLATGLLCAVPASAASGCFLYADGNGQTLSSEGDCSSQLPPASTFKIPL ALMGYDSGFLVNEEHPALPYKPSYDGWLPAWRETTTPRRWETYSVVWFSQQITE WLGMERFQQYVDRFDYGNRDLSGNPGKHDGLTQAWLSSSLAISPEEQARFLGKM VSGKLPVSAQTLQYTANILKVSEVEGWQIHGKTGMGYPKKLDGSLNRDQQIGWFV GWASKPGKQLIFVHTVVQKPGKQFASIKAKEEVLAALPAQLKKL SEQ ID No. 348: IACLSSTALAGSITENTSWNKEFSAEAVNGVFVLCKSSSKSCATNDLARASKEYLPA STFKIPNAIIGLETGVIKNEHQVFKWDGKPRAMKQWERDLTLRGAIQVSAVPVFQQI AREVGEVRMQKYLKKFSYGNQNISGGIDKFWLEDQLRISAVNQVEFLESLYLNKLSA SKENQLIVKEALVTEAAPEYLVHSKTGFSGVGTESNPGVAWWVGWVEKETEVYFF AFNMDIDNESKLPLRKSIPTKIMESEGIIGG SEQ ID No. 349: MKKILLLHMLVFVSATLPISSVASDEVETLKCTIIADAITGNTLYETGECARRVSPCSS FKLPLAIMGFDSGILQSPKSPTWELKPEYNPSPRDRTYKQVYPALWQSDSVVWFSQ QLTSRLGVDRFTEYVKKFEYGNQDVSGDSGKHNGLTQSWLMSSLTISPKEQIQFLL RFVAHKLPVSEAAYDMAYATIPQYQAAEGWAVHGKSGSGWLRDNNGKINESRPQ GWFVGWAEKNGRQVVFARLEIGKEKSDIPGGSKAREDILVELPVLMGNK SEQ ID No. 350: MAIRIFAILFSIFSLATFAHAQEGTLERSDWRKFFSEFQAKGTIWADERQADRAMLV FDPVRSKKRYSPASTFKIPHTLFALDAGAVRDEFQIFRWDGVNRGFAGHNQDQDLR SAMRNSTVWVYELFAKEIGDDKARRYLKKIDYGNAGPSTSNGDYWIEGSLAISAQE QIAFLRKLYRNELPFRVEHQRLVKDLMIVEAGRNWILRAKTGWEGRMGWWVGWVE WPTGSVFFALNIDTPNRMDDLFKREAIVRAILRSIEALPPNPAVNSDAAR SEQ ID No. 351: MQRSLSMSGKRHFIFAVSFVISTVCLTFSPANAAQKLSCTLVIDEASGDLLHREGSC DKAFAPMSTFKLPLAIMGYDADILLDATTPRWDYKPEFNGYKSQQKPTDPTIWLKDS IVWYSQELTRRLGESRFSDYVQRFDYGNKDVSGDPGKHNGLTHAWLASSLKISPEE QVRFLRRFLRGELPVSEDALEMTKAVVPHFEAGDWDVQGKTGTGSLSDAKGGKAP IGWFIGWATRDDRRVVFARLTVGARKGEQPAGPAARDEFLNTLPALSENF SEQ ID No. 352: MKTFAAYVIIACLSSTALAGSITENTSWNKEFSAEAVNGVFVLCKSSSKSCATNDLAR ASKEYLPASTFKIPNAIIGLETGVIKNEHQVFKWDGKPRAMKQWERDLTLRGAIQVS AVPVFQQIAREVGEVRMQKYLKKFSYGNQNISGGIDKFWLEGQLRISAVNQVEFLE SLYLNKLSASKENQLIVKEALVTEAAPEYLVHSKTGFSGVGTESNPGVAWWVGWVE KETEVYFFAFNMDIDNESKLPLRKSIPTKIMESEGIIGG SEQ ID No. 353: IACLSSTALAGSITENTSWNKEFSAEAVNGVFVLCKSSSKSCATNDLARASKEYLPA STFKIPNAIIGLETGVIKNEHQVFKWDGKPRAMKQWERDLTLRGAIQVSAVPVFQQIT REVGEVRMQKYLKKFSYGNQNISGGIDKFWLEDQLRISAVNQVEFLESLYLNKLSAS KENQLIVKEALVTEAAPEYLVHSKTGFSGVGTESNPGVAWWVGWVEKETEVYFFA FNMDIDNESKLPLRKSIPTKIMESEGIIGG SEQ ID No. 354: IACLSSTALAGSITENTSWNKEFSAEAVNGVFVLCKSSSKSCATNDLARASKEYLPA STFKIPSAIIGLETGVIKNEHQVFKWDGKPRAMKQWERDLTLRGAIQVSAVPVFQQIA REVGEVRMQKYLKKFSYGNQNISGGIDKFWLEGQLRISAVNQVEFLESLYLNKLSAS KENQLIVKEALVTEAAPEYLVHSKTGFSGVGTESNPGVAWWVGWVEKETEVYFFA FNMDIDNESKLPLRKSIPTKIMESEGIIGG SEQ ID No. 355: MIIRFLALLFSAVVLVSLGHAQEKTHESSNWGKYFSDFNAKGTIVVVDERTNGNSTS VYNESRAQQRYSPASTFKIPHTLFALDAGAVRDEFHVFRWDGAKRSFAGHNQDQN LRSAMRNSTVWVYQLFAKEIGENKARSYLEKLNYGNADPSTKSGDYWIDGNLAISA NEQISILKKLYRNELPFRVEHQRLVKDLMIVEAKRDWILRAKTGWDGQMGWWVGW VEWPTGPVFFALNIDTPNRMEDLHKREAIARAILQSVNALPPN SEQ ID No. 356: MAIRIFAILFSTFVFGTFAHAQEGMRERSDWRKFFSEFQAKGTIVVADERQTDRVILV FDQVRSEKRYSPASTFKIPHTLFALDAGAARDEFQVFRWDGIKRSFAAHNQDQDLR SAMRNSTVWIYELFAKEIGEDKARRYLKQIDYGNADPSTSNGDYWIDGNLAIAAQEQ IAFLRKLYHNELPFRVEHQRLVKDLMIVEAGRNWILRAKTGWEGRIGWWVGWVEW PTGPVFFALNIDTPNRMDDLFKREAIVRAILRSIEALPPNPAVNSDAAR SEQ ID No. 357: MKTFAAYVITACLSSTALASSITENTSWNKEFSAEAVNGVFVLCKSSSKSCATNNLA RASKEYLPASTFKIPSAIIGLETGVIKNEHQVFKWDGKPRAMKQWERDLSLRGAIQV SAVPVFQQIAREVGEVRMQKYLKKFSYGNQNISGGIDKFWLEGQLRISAVNQVEFL ESLFLNKLSASKENQLIVKEALVTEAAPEYLVHSKTGFSGVGTESNPGVAWWVGWV EKGTEVYFFAFNMDIDNENKLPLRKSIPTKIMASEGIIGG SEQ ID No. 358: MKTFAAYVITACLSSTALASSITENTSWNKEFSAEAVNGVFVLCKSSSKSCATNNLA RASKEYLPASTFKIPNAIIGLETGVSKNEHQVFKWDGKPRAMKQWERDLSLRGAIQV SAVPVFQQIAREVGEVRMQKYLKKFSYGNQNISGGIDKFWLEDQLRISAVNQVEFLE SLFLNKLSASKENQLIVKEALVTEAAPEYLVHSKTGFSGVGTESNPGVAWWVGWVE KGTEVYFFAFNMDIDNENKLPLRKSIPTKIMASEGIIGG SEQ ID No. 359: MKTFAAYVITACLSSTALASSITENTSWNKEFSAEAVNGVFVLCKSSSKSCATNNLA RASKEYLPASTFKIPNAIIGLETGVIKNEHQVFKWDGKPRAMKQWERDLSLRGAIQV SAVPVFQQIAREVGEVRMQKYLKKFSYGNQNISGGIDKFGLEGQLRISAVNQVEFLE SLFLNKLSASKENQLIVKEALVTEAAPEYLVHSKTGFSGVGTESNPGVAWWVGWVE KGTEVYFFAFNMDIDNENKLPLRKSIPTKIMASEGIIGG SEQ ID No. 360: MKNTIHINFAIFLIIANIIYSSASASTDISTVASPLFEGTEGCFLLYDASTNAEIAQFNKA KCATQMAPDSTFKIALSLMAFDAEIIDQKTIFKWDKTPKGMEIWNSNHTPKTWMQFS VVWVSQEITQKIGLNKIKNYLKDFDYGNQDFSGDKERNNGLTEAWLESSLKISPEEQ IQFLRKIINHNLPVKNSAIENTIENMYLQDLDNSTKLYGKTGAGFTANRTLQNGWFEG FIISKSGHKYVFVSALTGNLGSNLTSSIKAKKNAITILNTLNL SEQ ID No. 361: ANIIYSSASASTDISTVASPLFEGTEGCFLLYDVSTNAEIAQFNKAKCATQMAPDSTF KIALSLMAFDAEIIDQKTIFKWDKTPKGMEIWNSNHTPKTWMQFSVVWVSQEITQKI GLNKIKNYLKDFDYGNQDFSGDKERNNGLTEAWLESSLKISPEEQIQFLRKIINHNLP VKNSAIENTIENMYLQDLENSTKLYGKTGAGFTANRTLQNGWFEGFIISKSGHKYVF VSALTGNLGSNLTSSIKAKKNAITIL SEQ ID No. 362: IFSLATFAHAQEGTLERSDWRKFFSEFQAKGTIVVADERQADRAMLVFDPVRSKKR YSPASTFKIPHTLFALDAGAVRDEFQIFRWDGVNRGFAGHNQDQDLRSAMRNSTV WVYELFAKEIGDDKARRYLKKIDYGNAYPSTSNGDYWIEGSLAISAQEQIAFLRKLYR NELPFRVEHQRLVKDLMIVEAGRNWILRAKTGWEGRMGWWVGWVEWPTGSVFFA LNIDTPNRMDDLFKREAIVRAIL SEQ ID No. 363: MIIRFLALLFSAVVLVSLGHAQDKTHESSNWGKYFSDFNAKGTIVVVDERTNGNSTS VYNESRAQQRYSPASTFKIPHTLFALDAGAVRDEFHVFRWDGAKRSFAGHNQDQN LRSAMRNSTVWVYQLFAKEIGENKARSYLEKLNYGNADPSTKSGDYWIDGNLAISA NEQISILKKLYRNELPFRVEHQRLVKDLMIVEAKRDWILRAKTGWDGQMGWWVGW VEWPTGPVFFALNIDTPNRMEDLHKREAIARAILQSVNALPPN SEQ ID No. 364: MKKFILPIFSISILVSLSACSSIKTKSEDNFHISSQQHEKAIKSYFDEAQTQGVIIIKEGK NLSTYGNALARANKEYVPASTFKMLNALIGLENHKATTNEIFKWDGKKRTYPMWEK DMTLGEAMALSAVPVYQELARRTGLELMQKEVKRVNFGNTNIGTQVDNFWLVGPL KITPVQEVNFADDLAHNRLPFKLETQEEVEKMLLIKEVNGSKIYAKSGWGMGVTPQV GWLTGWVEQANGKKIPFSLNLEMKEGMSGSIRNEITYKLLENLGII SEQ ID No. 365: MKKFILPIFSISILVSLSACSSIKTKSEDNFHISSQQHEKAIKSYFDEAQTQGVIIIKEGK NLSTYGNALARANKEYVPASTFKMLNALIGLENHKATTNEIFKWDGKKRTYPMWEK DMTLGEAMALSAVPVYQELARRTGLELMQKEVKRVNFGNTNIGTQVDNFWLVGPL KITPVQEVNFADDLAHNRLPFKLETQEEVKKMLLIKEVNGSKIYAKSGWGMGVTPQV GWLTGWVEQANGKKIPFSLNLEMKEGMTGSIRNEITYKSLENLGII SEQ ID No. 366: MNKYFTCYVVASLFLSGCTVQHNLINETPSQIVQGHNQVIHQYFDEKNTSGVLVIQT DKKINLYGNALSRANTEYVPASTFKMLNALIGLENQKADINEIFKWKGEKRSFTAWE KDMTLGEAMKLSAVPVYQELARRIGLDLMQKEVKRIGFGNAEIGQQVDNFWLVGPL KVTPIQEVEFVSQLAHTQLPFSEKVQANVKNMLLLEESNGYKIFGKTGWAMDIKPQV GWLTGWVEQPDGKIVAFALKMEMRSEMPASIRNELLMKSLKQLNII SEQ ID No. 367: MAIRIFAILFSIFSLATFAHAQEGTLERSDWRKFFSEFQAKGTIVVADERQADRAMLV FDPVRSKKRYSPASTFKIPHTLFALDAGAVRDEFQIFRWDGVNRGFAGHNQDQDLR SAMRNSTVWVYELFAKEIGDDKARRYLKKIDYGNADPSTSNGDYCIEGSLAISAQEQ IAFLRKLYRNELPFRVEHQRLVKDLMIVEAGRNWILRAKTGWEGRMGWWVGWVE WPTGSVFFALNIDTPNRMDDLFKREAIVRAIL SEQ ID No. 368: MKTFAAYVITACLSSTALASSITENTSWNKEFSAEAVNGVFVLCKSSSKSCATNNLA RASKEYLPASTFKIPNAIIGLETGVIKNEHQVFKWDGKPRAMKQWERDLSLRGAIQV SAVPVFQQIAREVGEVRMQKYLKKFSYGNQNISGGIDKFWLEGQLRISAVNQVEFL ESLFLNKLSASKENQLIVKEALVTEAAPEYLVHSKTGFSGVGTESNPGVAWWVGWV EKGTEVYFFAFNMDIDNENKLPLRKSIPTKIMASEGIIGG SEQ ID No. 369: MAIRFLTILLSTFFLTSFVHAQEHVLERSDWKKFFSDLRAEGAIVISDERQAEHALLVF GQERAAKRYSPASTFKLPHTLFALDADAVRDEFQVFRWDGVKRSFAGHNQDQDLR SAMRNSAVWVYELFAKEIGKDKARHYLKQIDYGNADPSTIKGDYWIDGNLEISAHEQ ISFLRKLYRNQLPFQVEHQRLVKDLMITEAGRNWILRAKTGWEGRFGWWVGWVE WPTGPVFFALNIDTPNRTDDLFKREAIARAILRSIDALPPN SEQ ID No. 370: MAIRIFAILFSIFSLATFAHAQEGTLERSDWRKFFSEFQAKGTIVVADERQADRAMLV FDPVRSKKRYSPASTFKIPHTLFALDAGAVRDEFQIFRWDGVNRGFAGHNQDQDLR SAMRNSTVWVYELFAKEIGDDKARRYLKKIDYGNADPSTSNGDYWIEGSIAISAQEQ IAFLRKLYRNELPFRVEHQRLVKDLMIVEAGRNWILRAKTGWEGRMGWWVGWVE WPTGSVFFALNIDTPNRMDDLFKREAIVRAILRSIEALPPNPAVNSDAAR SEQ ID No. 371: MKKFILPIFSISILVSLSACSSIKTKSEDNFHISSQQHEKAIKSYFDEAQTQGVIIIKEGK NLSTYGNALARANKEYVPASTFKMLNALIGLENHKATTNEIFKWDGKKRTYPMWEK DMTLGEAMALSAVPVYQELARRTGLELMQKEVKRVNFGNTNIGTQVDNFWLVGPL KITPVQEVNFADDLAHNRLPFKLETQEEVKKMLLIKEVNGSKIYAKSGWGMGVTPQV GWLTGWVEQANGKKIPFSLNLEMKEGMSGSIRNEITYKSLENLGII SEQ ID No. 372: MAIRFLTILLSTFFLTSFVHAQEHVLERSDWKKFFSDLRAEGAIVISDERQAEHALLVF GQERAAKRYSPASTFKLPHTLFALDADAVRDEFQVFRWDGVKRSFAGHNQDQDLR SAMRNSAVVWYELFAKEIGEDKARRYLKQIDYGNADPSTIKGDYWIDGNLEISAHEQ ISFLRKLYRNQLPFQVEHQRLVKDLMITEAGRNWILRAKTGWEGRFGWWVGWVE WPTGPVFFALNIDTPNRTDDLFKREAIARAILRSIDALPPN SEQ ID No. 373: MAIRFFTILLSTFFLTSFVYAQEHVVIRSDWKKFFSDLQAEGAIVIADERQAKHTLSVF DQERAAKRYSPASTFKIPHTLFALDADAVRDEFQVFRWDGVNRSFAGHNQDQDLR SAMRNSTVWVYELFAKDIGEDKARRYLKQIDYGNVDPSTIKGDYWIDGNLKISAHEQ ILFLRKLYRNQLPFKVEHQRLVKDLMITEAGRSWILRAKTGWEGRFGWWVGWIEW PTGPVFFALNIDTPNRTDDLFKREAIARAILRSIDALPPN SEQ ID No. 374: MNKYFTCYVVASLFLSGCTVQHNLINETPSQIVQGHNQVIHQYFDEKNTSGVLVIQT DKKINLYGNALSRANTEYVPASTFKMLNALIGLENQKTDINEIFKWKGEKRSFTAWE KDMTLGEAMKLSAVPVYQELARRIGLDLMQKEVERIGFGNAEIGQQVDNFWLVGPL KVTPIQEVEFVSQLAHTQLPFSEKVQANVKNMLLLEESNGYKIFGKTGWAAMDIKPQ VGWLTGWVEQPDGKIVAFALNMEMRSEMPASIRNELLMKSLKQLNII SEQ ID No. 375: MAIQIFAILFSTFVLATFAHAQDGTLERSDWGKFFSDFQAKGTIVVADERQADHAILV FDQARSMKRYSPASTFKIPHTLFALDAGAVRDEFQIFRWDGVKRSFAGHNKDQDLR SAMRNSTVWVYELFAKEIGDGKARRYLKQIGYGNADPSTSHGDYWIEGSLAISAQE QIAFLRKLYQNDLPFRVEHQRLVKDLMIVEAGRNWILRAKTGWEGSMGWWVGWV EWPTGPVFFALNIDTPNRMDDLFKREAIARAILLSIEALPPNPAVHSDAAR SEQ ID No. 376: MKNTIHINFAIFLIIANIIYSSASASTDISTVASQLFEGTEGCFLLYDASTNAEIAQFNKA KCAAQMAPDSTFKIALSLMAFDAEIIDQKTIFKWDKIPKGMEIWNSNHTPKTWMQFS VVWVSQEITQKIGLNKIKNYLKDFDYGNQDFSGDKERNNGLTEAWLESSLKISPEEQ IQFLRKIINHNLPVRNSAIENTIDNMYLQDLENSTKLYGKTGAGFTANRTLQNGWFEG FIISKSGHKYVFVSALTGSLGSNLTSSIKAKKNAITILNTLNL SEQ ID No. 377: MLLFMFSIISFGNENQFMKEIFERKGLNGTFVVYDLKNDKIDYYNLDRANERFYPASS FKIFNTLIGLENGIVKNVDEMFYYYDGSKVFLDSWAKDSNLRYAIKVSQVPAYKKLAR ELGKERMQEGLNKLNYGNKEIGSEIDKFWLEGPLKISAMEQVKLLNLLSQSKLPFKL ENQEQVKDITILEKKDDFILHGKTGWATDNIWPIGWFVGWIETSDNIYSFAINLDISD SKFLPKREEIVREYFKNINVIK SEQ ID No. 378: MRVLALSAVFLVASIIGMPAVAKEWQENKSWNAHFTEHKSQGVVVLWNENKQQGF TNNLKRANQAFLPASTFKIPNSLIALDLGVVKDEHQVFKWDGQTRDIATWNRDHNLI TAMKYSVVPVYQEFARQIGEARMSKMLHAFDYGNEDISGNVDSFWLDGGIRISATE QISFLRKLYHNKLHVSERSQRIVKQAMLTEANGDYIIRAKTGYSTRIEPKIGWWVGW VELDDNVWFFAMNMDMPTSDGLGLRQAITKEVLKQEKIIP SEQ ID No. 379: MLSRYSKTLAFAVVACTLAISTATAHAELWRNDLKRVFDDAGVSGTFVLMDITADR TYVVDPARAARSIHPASTFKIPNSLIAFDTGAVRDDQEVLPYGGKPQPYEQWEHDM ALPEAIRLSAVPIYQEVARRVGFERMQAYVDAFDYGNRQLGSAIDQFWLRGPLEISA FEEARFTSRMALKQLPVKPRTWDMVQRMLLIEQQGDAALYAKTGVATEYQPEIGW WAGWVERAGHVYAFALNIDMPREGDMAKRIPLGKQLMRALEVWPAP SEQ ID No. 380: MRPLLFSALLLLSGHTQASEWNDSQAVDKLFGAAGVKGTFVLYDVQRQRYVGHDR ERAETRFVPASTYKVANSLIGLSTGAVRSADEVLPYGGKPQRFKAWEHDMSLRDAI KASNVPVYQELARRIGLERMRANVSRLGYGNAEIGQVVDNFWLVGPLKISAMEQTR FLLRLAQGELPFPAPVQSTVRAMTLLESGPGWELHGKTGWCFDCTPELGWWVGW VKRNERLYGFALNIDMPGGEADIGKRVELGKASLKALGILP SEQ ID No. 381: MNKGLHRKRLSKRLLLPMLLCLLAQQTQAVAAEQTKVSDVCSEVTAEGWQEVRRW DKLFESAGVKGSLLLWDQKRSLGLSNNLSRAAEGFIPASTFKLPSSLIALETGAVRD ETSRFSWDGKVREIAVWNRDQSFRTAMKYSVVPVYQQLAREIGPKVMAAMVRQLE YGNQDIGGQADSFWLDGQLRITAFQQVDFLRQLHDNKLPVSERSQRIVKQMMLTE ASTDYIIRAKTGYGVRRTPAIGWWVGWLELDDNTVYFAVNLDLASASQLPLRQQLV KQVLKQEQLLP SEQ ID No. 382: MNTIISRRWRAGLWRRLVGAVVLPATLAATPAAYAADVPKAALGRITERADWGKLF AAEGVKGTIVVLDARTQTYQAYDAARAEKRMSPASTYKIFNSLLALDSGALDNERAII PWDGKPRRIKNWNAAMDLRTAFRVSCLPCYQVVSHKIGRRYAQAKLNEVGYGNRT IGGAPDAYWVDDSLQISAREQVDFVQRLARGTLPFSARSQDIVRQMSIVEATPDYVL HGKTGWFVDKKPDIGWWVGWIERDGNITSVAINIDMLSEADAPKRARIVKAVLKDLK LI SEQ ID No. 383: MKTFAAYVITACLSSTALASSITENTFWNKEFSAEAVNGVFVLCKSSSKSCATNNLA RASKEYLPASTFKIPNAIIGLETGVIKNEHQIFKWDGKPRAMKQWERDLSLRGAIQVS AVPVFQQIAREVGEVRMQKYLKKFSYGNQNISGGIDKFWLEGQLRISAVNQVEFLE SLFLNKLSASKENQLIVKEALVTEAAPEYLVHSKTGFSGVGTESNPGVAWWVGWVE KGAEVYFFAFNMDIDNENKLPLRKSIPTKIMASEGIIGG SEQ ID No. 384: MRVLALSAVLVVASIVGMPAMANEWQEKPSWNTHFSEHKAQGVIVLWNENKQQGF TNNLKRANQAFLPASTFKIPNSLIALDLGVVKDEHQVFKWDGQTRDIAAWNRDHDLI TAMKYSVVPVYQEFARQIGQARMSKMLHAFDYGNEDISGNLDSFWLDGGIRISATE QVAFLRKLYHNKLHVSERSQRIVKQAMLTEANSDYIIRAKTGYSTRIEPQIGWWVGW VELDDNVWFFAMNMDMPTADGLGLRQAITKEVLKQEKIIP SEQ ID No. 385: MKKITLFLLFLNLVFGQDKILNNWFKEYNTSGTFVFYDGKTWASNDFSRAMETFSPA STFKIFNALIALDSGVIKTKKEIFYHYRGEKVFLSSWAQDMNLSSAIKYSNVLAFKEVA RRIGIKTMQEYLNKLHYGNAKISKIDTFWLDNSLKISAKEQAILLFRLSQNSLPFSQEA MNSVKEMIYLKNMENLELFGKTGFNDGQKIAWIVGFVYLKDENKYKAFALNLDIDKF EDLYKREKILEKYLDELVKKVKNDG SEQ ID No. 386: MSKKNFILIFIFVILISCKNTEKISNETTLIDNIFTNSNAEGTLVIYNLNDDKYIIHNKERAE QRFYPASTFKIYNSLIGLNEKAVKDVDEVFYKLMAKSFLESWAKDSNLRYAIKNSQV PAYKELARRIGIKKMKENIEKLDFGNKSIGDSVDTFWLEGPLEISAMEQVKLLTKLAQ NELQYPIEIQKAISDITITRANLHITLHGKTGLADSKNMTTEPIGWFVGWLEENDNIYV FALNIDNINSDDLAKRINIVKESLKALNLLK SEQ ID No. 387: MNKYFTCYVVASLFLSGCTVQHNLINETPSQIVQGHNQVIHQYFDEKNTSGVLVIQT DKKINLYGNALSRANTEYVPASTFKMLNALIGLENQKTDINEIFKWKGEKRSFTAWE KDMTLGEAMKLSAVPVYQELARRIGLDLMQKEVKRIGFGNAEIGQQVDNFWLVGPL KVTPIQEVEFVSQLAHTQLPFSEKVQANVKNMLLLEESNGYKIFGKTGWAMDIKPQV GWLTGWVEQPDGKIVAFALKMEMRSEMPASIRNELLMKSLKQLNII SEQ ID No. 388: MNIQALLLITSAIFISACSPYIVTANPNYSASKSDEKAEKIKNLFNEAHTTGVLVIQQGQ TQQSYGNDLARASTEYVPASTFKMLNALIGLEHHKATTTEVFKWDGQKRLFPEWEK NMTLGDAMKASAIPVYQDLARRIGLELMSNEVKRIGYGNADIGTQVDNFWLVGPLKI TPQQEAQFAYKLANKTLPFSQKVQDEVQSMLFIEEKNGNKIYAKSGWGWDVNPQV GWLTGWVVQPQGNIVAFSLNLEMKKGISSSVRKEITYRGLEQLGIL SEQ ID No. 389: MNIKALLLITSAIFISACSPYIVTANPNHSASKSDEKGEKIKNLFNEAHTTGVLVIQQGQ TQQSYGNDLARASTEYVPASTFKMLNALIGLEHHKATTTEVFKWDGQKRLFPEWEK DMTLGDAMKASAIPVYQDLARRIGLELMSKEVKRVGYGNADIGTQVDNFWLVGPLK ITPQQEAQFAYKLANKTLPFSPKVQDEVQSMLFIEEKNGNKIYAKSGWGWDVDPQV GWLTGWVVQPQGNIVAFSLNLEMKKGIPSSVRKEITYKSLEQLGIL SEQ ID No. 390: MNIKALLLITSAIFISACSPYIVTANPNHSASKSDEKAEKIKNLFNEAHTTGVLVIQQGQ TQQSYGNDLARASTEYVPASTFKMLNALIGLEHHKATTTEVFKWDGKKRLFPEWEK DMTLGDAMKASAIPVYQDLARRIGLELMSKEVKRVGYGNADIGTQVDNFWLVGPLK ITPQQEAQFAYKLANKTLPFSQKVQDEVQSMLFIEEKNGNKIYAKSGWGWDVNPQV GWLTGWVVQPQGNIVAFSLNLEMKKGIPSSVRKEITYKSLEQLGIL SEQ ID No. 391: MNIKALLLITSAIFISACSPYIVTANPNHSASKSDVKAEKIKNLFNEAHTTGVLVIQQGQ TQQSYGNDLARASTEYVPASTFKMLNALIGLEHHKATTTEVFKWDGKKRLFPEWEK DMTLGDAMKASAIPVYQDLARRIGLELMSKEVKRVGYGNADIGTQVDNFWLVGPLK ITPQQEAQFAYKLANKTLPFSQKVQDEVQSMLFIEEKNGNKIYAKSGWGWDVNPQV GWLTGWVVQPQGNIVAFSLNLEMKKGIPSSVRKEITYKSLEQLGIL SEQ ID No. 392: MNIKALLLITSAIFISACSPYIVSANPNHSASKSDEKAEKIKNLFNEAHTTGVLVIQQGQ TQQSYGNDLARASTEYVPASTFKMLNALIGLEHHKATTTEVFKWDGQKRLFPEWEK NMTLGDAMKASAIPVYQDLARRIGLELMSNEVKRVGYGNADIGTQVDNFWLVGPLK ITPQQEAQFAYKLANKTLPFSQEVQDEVQSMLFIEEKNGNKIYAKSGWGWDVNPQV GWLTGWVVQPQGNIVAFSLNLEMKKGIPSSVRKEITYKSLEQLGIL SEQ ID No. 393: MNIKALLLITSAIFISACSPYIVTANPNHSASKSDDKAEKIKNLFNEAHTTGVLVIHQGQ TQQSYGNDLARASTEYVPASTFKMLNALIGLEHHKATTTEVFKWDGEKRLFPEWEK NMTLGDAMKASAIPVYQDLARRIGLELMSKEVKRVGYGNADIGTQVDNFWLVGPLK ITPQQEAQFAYKLANKTLPFSQKVQDEVQSMLFIEEKNGNKIYAKSGWGWDVNPQV GWLTGWVVQPQGNIVAFSLNLEMKKGIPSSVRKEITYKSLEQLGIL SEQ ID No. 394: MNIKALLLITSAIFISACSPYIVTANPNHSASKSDKKAEKIKNLFNEAHTTGVLVIQQGQ TQQSYGNDLARASTEYVPASTFKMLNALIGLEHHKATTTEVFKWNGQKRLFPEWEK DMTLGDAMKASAIPVYQDLARRIGLELMSNEVKRVGYGNADIGTQVDNFWLVGPLK ITPQQEAQFAYKLANKTLPFSQKVQHEVQSMLFIEEKNGNKIYAKSGWGWDVDPQV GWLTGWVVQPQGNIVAFSLNLEMKKGIPSSVRKEITYKSLEQLGIL SEQ ID No. 395: MNIKALLLITSAIFISACSPYIVTANPNHSASKSDEKAEKIKNLFNEAHTTGVLVIQQGQ TQQSYGNDLARASTEYVPASTFKMLNALIGLEHHKTTTTEVFKWDGQKRLFPEWEK DMTLGDAMKASAIPVYQDLARRIGLELMSKEVKRVGYGNADIGTQVDNFWLVGPLK ITPQQEAQFAYKLANKTLPFSPKVQDEVQSMLFIEEKNGNKIYAKSGWGWDVDPQV GWLTGWVVQPQGNIVAFSLNLEMKKGIPSSVRKEITYKSLEQLGIL SEQ ID No. 396: MNIKALLLITSAIFISACSPYIVSANPNHSASKSDEKAEKIKNLFNEAHTTGVLVIQQGQ TQQSYGNDLARASTEYVPASTFKMLNALIGLEHHKATTTAVFKWDGQKRLFPEWEK NMTLGDAMKASAIPVYQDLARRIGLELMSNEVKRVGYGNADIGTQVDNFWLVGPLK ITPQQEAQFAYKLANKTLPFSQKVQDEVQSMLFIEEKNGNKIYAKSGWGWDVNPQV GWLTGWVVQPQGNIVAFSLNLEMKKGTPSSVRKEITYKSLEQLGIL SEQ ID No. 397: MNIKALLLITSAIFISACSPYIVSANPNHSASKSDEKAEKIKNLFNEAHTTGVLVIQQGQ TQQSYGNDLARASTEYVPASTFKMLNALIGLEHHKATTTEVFKWDGQKRLFPEWEK NMTLGDAMKASAIPVYQDLPRRIGLELMSNEVKRVGYGNADIGTQVDNFWLVGPLK ITPQQEAQFAYKLANKTLPFSQKVQDEVQSMLFIEEKNGNKIYAKSGWGWDVNPQV GWLTGWVVQPQGNIVAFSLNLEMKKGIPSSVRKEITYKSLEQLGIL SEQ ID No. 398: MNIKALLLITSAIFISACSPYIVTANPNHSASKSDVKAEKIKNLFNEAHTTGVLVIQQGQ TQQSYGNDLARASTEYVPASTFKMLNALIGLEHHKATTTEVFKWDGKKRLFPEWEK DMTLGDAMKASAIPVYQDLARRIGLELMSKEVKRVGYGNADIGTQVDNFWLVGPLK ITPQQEAQFAYKLANKTLPFSQKVQDEVQSMLFIEEKNGNKIYAKSGWGWDVNPQV GWLTGWVVQPQGNIVAFSLNLEMKKGIPSSVRKEITYKSLEKLGIL SEQ ID No. 399: MNIKTLLLITSTIFISACSPYIVTANPNHSTSKSDEKAEKIKNLFNEAHTTGVLVIQQGQ TQQSYGNDLARASIEYVPASTFKMLNALIGLEHHKATTTEIFKWDGQKRLFPEWEKD MTLGDAMKASAIPVYQDLARRIGLELMSKEVKRVGYGNADIGTQVDNFWLVGPLKIT PQQEAQFAYKLANKTLPFSLKVQDEVQSMLFIEEKNGNKIYAKSGWGWDVDPQVG WLTGWVVQPQGNIVAFSLNLEMKKGIPSSVRKEITYKSLEQLGIL SEQ ID No. 400: MNIKALLLITSAIFISACSPYIVTANPNHSASKSDVKAEKIKNLFNEAHTTGVLVIQQGQ TQQSYGNDLARASTEYVPASTFKMLNALIGLEHHKATTTEVFKWDGKKRLFPEWEK DMTLGDAMKASAISVYQDLARRIGLELMSKEVKRVGYGNADIGTQVDNFWLAGPL KITPQQEAQFAYKLANKTLPFSQKVQDEVQSMLFIEEKNGNKIYAKSGWGWDVNPQV GWLTGWVVQPQGNIVAFSLNLEMKKGIPSSVRKEITYKSLEQLGIL SEQ ID No. 401: MNIKALLLITSAIFISACSPYIVTANPNHSASKSDVKAEKIKNLFNEAHTTGVLVIQQGQ TQQSYGNDLARASTEYVPASTFKMLNALIGLEHHKATTTEVFKWDGKKRLFPEWEK DMTLGDAMKASALPVYQDLARRIGLELMSKEVKRVGYGNADIGTQVDNFWLVGPL KITPGQEAQFAYKLANKTLPFSQKVQDEVQSMLFIEEKNGNKIYAKSGWGWDVNPQ VGWLTGWVVQPQGNIVAFSLNLEMKKGIPSSVRKEITYKSLEQLGIL SEQ ID No. 402: MNIKALLLITSAIFISACSPYIVTANPNHSASKSDDKAEKIKNLFNEAHTTGVLVIHQGQ TQQSYGNDLARASTEYVPASTFKMLNALIGLEHHKATTTEVFKWDGEKRLFPEWEK NMTLGDAMKASAIPVYQDLARRIGLELMSKEVKRVGYGNADIGTQVDNFWLVGPLK ITPQQEAQFAYKLANKTLPFSQKVQDEVQSMLFIEEKNGNKIYAKSGWGWDVNPQV GWLTGSVVQPQGNIVAFSLNLEMKKGIPSSVRKEITYKSLEQLGIL SEQ ID No. 403: MNIKTLLLITSTIFISACSPYIVTANPNHSTSKSDEKAEKIKNLFNEAHTTGVLVIQQGQ TQQSYGNDLARASIEYVPASTFKMLNALIGLEHHKATTTEIFKWDGQKRLFPEWEKD MTLGDAMKASAIPVYQDLARRIGLELMSKEVKRVGYGNADIGTQVDNFWLVGPLKIT PQQEAQFAYKLANKTLPFSLKAQDEVQSMLFIEEKNGNKIYAKSGWGWDVDPQVG WLTGWVVQPQGNIVAFSLNLEMKKGIPSSVRKEITYKSLEQLGIL SEQ ID No. 404: MNIKALLLITSAIFISACSPYIVTANPNHSASKSDKKAEKIKNLFNEAHTTGVLVIQQGQ TQQSYGNDLARASTEYVPASTFKMLNALIGLEHHKATTTEVFKWDGKKRLFPEWEK DMTLGDAMKASAIPVYQDLARRIGLELMSKEVKRVGYGNADIGTQVDNFWLVGPLK ITPQQEAQFAYKLANKTLPFSQKVQDEVQSMLFIEEKNGNKIYAKSGWGWDVNPQV GWLTGWVVQPQGNIVAFSLNLEMKKGIPSSVRKEITYKSLEQLGIL SEQ ID No. 405: MNIKTLLLITSAIFISACSHYIVSANPNHSASKSDEKAEKIKNLFNEAHTTGVLVIQQGQ TQQSYGNDLARASTEYVPASTFKMLNALIGLEHHKATTTEVFKWDGQKRLFPEWEK NMTLGDAMKASAIPVYQDLARRIGLELMSNEVKRVGYGNADIGTQVDNFWLVGPLK ITPQQEAQFTYKLANKTLPFSQKVQDEVQSMLFIEEKNGNKIYAKSGWGWDVNPQV GWLTGWVVQPQGNIVAFSLNLEMKKGIPSSVRKEITYKSLEQLGIL SEQ ID No. 406: MNIKALLLITSAIFISACSPYIVSANPNHSASKSDEKAEKIKNLFNEAHTTGVLVIQQGQ TQQSYGNDLARASTEYVPASTFKMLNALIGLEHHKATTTEVFKWDGQKRLFPEWEK NMTLGDAMKASAIPVYQDLARRIGLELMSNEVKRVGYGNADIGTQVDNFWLVGPLK ITPQQEAQFAYKLANKTLPFSQKVQDEVQSMLFIEEKNGNKIYAKSGWGWDVDPQV GWLTGWVVQPQGNIVAFSLNLEMKKGIPSSVRKEITYKSLEQLGIL SEQ ID No. 407: MNIKALLLITSTIFISACSPYIVTANPNHSASKSDEKAEKIKNLFNEAHTTGVLVIQQGQ TQQSYGNDLARASTEYVPASTFKMLNALISLEHHKATTTEVFKWDGQKRLFPEWEK DMTLGDAMKASAIPVYQDLARRIGLELMSNEVKRVGYGNADIGTQVDNFWLVGPLK ITPQQEAQFAYKLANKTLPFSQKVQDEVQSMLFIEEKNGNKIYAKSGWGWDVNPQV GWLTGWVVQPQGNIVAFSLNLEMKKGIPSSVRKEITYKSLEQLGIL SEQ ID No. 408: MNIQALLLITSAIFISACSPYIVSANPNHSASKSDEKAEKIKNLFNEAHTTGVLVIQQGQ TQQSYGNDLARASTEYVPASTFKMLNALIGLEHHKATTTEVFKWDGKKRLFPEWEK DMTLGDAMKASAIPVYQDLARRIGLELMSKEVKRVGYGNADIGTQVDNFWLVGPLK ITPQQEAQFAYKLANKTLPFSQKVQDEVQSMLFIEEKNGNKIYAKSGWGWDVNPQV GWLTGWVVQPHGNIVAFSLNLEMKKGIPSSVRKEITYKSLEQLGIL SEQ ID No. 409: MNIKALFLITSAIFISACSPYIVTANPNHSASKSDEKAEKIKNLFNEAHTTGVLVIQQGQ TQQSYGNDLARASTEYVPASTFKMLNALIGLEHHKATTTEVFKWDGKKRLFPEWEK DMTLGDAMKASAIPVYQDLARRIGLELMSKEVKRVGYGNADIGTQVDNFWLVGPLK ITPQQEAQFAYKLANKTLPFSQKVQDEVQSMLFIEEKNGNKIYAKSGWGWDVDPQV GWLTGWVVQPQGNIVAFSLNLEMKKGIPSSVRKEITYKSLEQLGIL SEQ ID No. 410: MKLLKILSLVCLSISIGACAEHSMSRAKTSTIPQVNNSIIDQNVQALFNEISADAVFVTY DGQNIKKYGTHLDRAKTAYIPASTFKIANALIGLENHKATSTEIFKWDGKPRFFKAWD KDFTLGEAMQASTVPVYQELARRIGPSLMQSELQRIGYGNMQMGTEVDQFWLKGP LTITPIQEVKFVYDLAQGQLPFKPEVQQQVKEMLYVERRGENRLYAKSGWGMAVD PQVGWYVGFVEKADGQVVAFALNMQMKAGDDIALRKQLSLDVLDKLGVFHYL SEQ ID No. 411: MNIKALLLITSTIFISACSPYIVTANPNHSTSKSDEKAEKIKNLFNEAHTTGVLVIQQGQ TQQSYGNDLARASTEYVPASTFKMLNALIGLEHHKATTTEIFKWDGQKRLFPEWEK DMTLGDAMKASAIPVYQDLARRIGLELMSKEVKRVGYGNADIGTQVDNFWLVGPLK ITPQQEAQFAYKLANKTLPFSLKVQDEVQSMLFIEEKNGNKIYAKSGWGWDVDPQV GWLTGWVVQPQGNIVAFSLNLEMKKGIPSSVRKEITYKSLEQLGIL SEQ ID No. 412: MNIKTLLLITSAIFISACSPYIVTANPNHSASKSDEKAEKIKNLFNEVHTTGVLVIRQGQ TQQSYGNDLARASTEYVPASTFKMLNALIGLEHHKATTTEVFKWDGQKRLFPEWEK DMTLGDAMKASAIPVYQDLARRIGLELMSKEVKRVGYGNADIGTQVDNFWLVGPLK ITPQQEAQFAYKLANKTLPFSPKVQDEVQSMLFIEEMNGNKIYAKSGWGWDVDPQV GWLTGWVVQPQGNIVAFSLNLEMKKGIPSSVRKEITYKSLEQLGIL SEQ ID No. 413: MKLLKILSLVCLSISIGACAEHSMSRAKTSTIPQVNNSIIDQNVQALFNEISGDAVFVTY DGQNIKKYGTHLDRAKTAYIPASTFKIANALIGLENHKATSTEIFKWDGKPRFFKAWD KDFTLGEAMQASTVPVYQELARRIGPSLMQSELQRIGYGNMQIGTEVDQFWLKGPL TITPIQEVKFVYDLAQGQLPFKPEVQQQVKEMLYVERRGENRLYAKSGWGMAVDP QVGWYVGFVEKADGQVVAFALNMQMKAGDDIALRKQLSLDVLDKLGVFHYL SEQ ID No. 414: MKKFILPIFSISILVSLSACSSIKTKSEDNFHISSQQHEKAIKSYFDEAQTQGVIIIKEGK NLSTYGNALARANKEYVPASTFKMLNALIGLENHKATTNEIFKWDGKKRTYPMWEK DMTLGEAMALSAVPVYQELARRTGLELMQKEVKRVNFGNTNIGTQVDNFWLVGPL KITPVQEVNFADDLAHNRLPFKLETQEEVKKMLLIKEVNGSKIYAKSGWGMDVTPQV GWLTGWVEQANGKKIPFSLNLEMKEGMSGSIRNEITYKSLENLGII SEQ ID No. 415: MAIRIFAILFSIFSLATFAHAQEGTLERSDWRKFFSEFQAKGTIVVADERQADRAMLV FDPVRSKKRYSPASTFKIPHTLFALDAGAVRDEFQIFRWDGVNRGFAGHNQDQDLR SAMRNSTVWVYELFAKEIGDDKARRYLKKIDYGNADPSTSNGDYWIESSLAISAQE QIAFLRKLYRNELPFRVEHQRLVKDLMIVEAGRNWILRAKTGWEGRMGWWVGWVE WPTGSVFFALNIDTPNRMDDLFKREAIVRAILRSIEALPPNPAVNSDAAR SEQ ID No. 416: MNIKALLLITSAIFISACSPYIVTANPNHSASKSDEKAEKIKNLFNEAHTTGVLVIQQGQ TQQSYGNDLARASTEYVPASTFKMLNALIGLEHHKATTTEVFKWDGKKRLFPEWEK NMTLGDAMKASAIPVYQDLARRIGLELMSNEVKRVGYGNADIGTQVDNFWLVGPLK ITPQQEAQFAYKLANKTLPFSQKVQDEVQSMLFIEEKNGNKIYAKSGWGWDVDPQV GWLTGWVVQPQGNIVAFSLNLEMKKGIPSSVRKEITYKSLEQLGIL SEQ ID No. 417: MNIKALLLITSAIFISACSPYIVTANPNHSASKSDVKAEKIKNLFNEAHTTGVLVIQQGQ TQQSYGNDLARASTEYVPASTFKMLNALIGLEHHKATTTEVFKWDGKKRLFPEWEK DMTLGDAMKASAILVYQDLARRIGLELMSKEVKRVGYGNADIGTQVDNFWVVGPLK ITPQQEAQFAYKLANKTLPFSQKVQDEVQSMLFIEEKNGNKIYAKSGWGWDVNPQV GWLTGWVVQPQGNIVAFSLNLEMKKGIPSSVRKEITYKSLEQLGIL SEQ ID No. 418: MNIKALLLITSAIFISACSPYIVTANPNHSASKSDKKAEKIKNLFNEAHTTGVLVIQQGQ TQQSYGNDLARASTEYVPASTFKMLNALIGLEHHKATTTEVFKWNGQKRLFPEWEK DMTLGDAMKASAIPVYQDLARRIGLELMSNEVKRVGYGNADIGTQVDNFWLVGPLK ITPQQEAQFAYKLANKTLPFSQKVQDEVQSMLFIEEKNGNKIYAKSGWGWDVDPQV GWLTGWVVQPQGNIVAFSLNLEMKKGIPSSVRKEITYKSLEQLGIL SEQ ID No. 419: MNIKALLLITSAIFISACSPYIVTANPNHSASKSDDKAEKIKNLFNEAHTTGVLVIHQGQ TQQSYGNDLARASTEYVPASTFKMLNALIGLEHHKATTTEVFKWDGEKRLFPEWEK NMTLGDAMKASAIPVYQDLARRIGLELMSKEVKRVGYGNADIGTQVDNFWVVGPLK ITPQQEAQFAYKLANKTLPFSQKVQDEVQSMLFIEEKNGNKIYAKSGWGWDVNPQV GWLTGWVVQPQGNIVAFSLNLEMKKGIPSSVRKEITYKSLEQLGIL SEQ ID No. 420: MNIKALLLITSAIFISACSPYIVTTNPNHSASKSDEKAEKIKNLFNEAHTTGVLVIQQGQ TQQSYGNDLARASTEYVPASTFKMLNALIGLEHHKATTTEVFKWDGKKRLFPEWEK DMTLGDAMKASAIPVYQDLARRIGLELMSKEVKRVGYGNTDIGTQVDNFWVVGPLK ITPQQEAQFAYKLANKTLPFSQKVQDEVQSMLFIEEKNGNKIYAKSGWGWDVDPQV GWLTGWVVQPQGNIVAFSLNLEMKKGIPSSVRKEITYKSLEQLGIL SEQ ID No. 421: MNIKALLLITSAIFISACSPYIVTANPNHSASKSDVKAEKIKNLFNEAHTTGVLVIQQGQ TQQSYGNDLARASTEYVPASTFKMLNALIGLEHHKATTTEVFKWDGKKRLFPEWEK DMTLGDAMKASAIQVYQDLARRIGLELMSKEVKRVGYGNADIGTQVDNFWLVGPLK ITPQQEAQFAYKLANKTLPFSQKVQDEVQSMLFIEEKNGNKIYAKSGWGWDVNPQV GWLTGWVVQPQGNIVAFSLNLEMKKGIPSSVRKEITYKSLEQLGIL SEQ ID No. 422: MNIKALLLITSAIFISACSPYIVTANPNHSASKSDDKAEKIKNLFNEAHTTGVLVIHQGQ TQQSYGNDLARASTEYVPASTFKMLNALIGLEHHKATTTEVFKWDGEKRLFPEWEK NMTLGDAMKASALPVYQDLARRIGLELMSKEVKRVGYGNADIGTQVDNFWLVGPL KITPQQEAQFAYKLANKTLPFSQKVQDEVQSMLFIEEKNGNKIYAKSGWGWDVNPQ VGWLTGWVVQPQGNIVAFSLNLEMKKGIPSSVRKEITYKSLEQLGIL SEQ ID No. 423: MNIKTLLLITSAIFISACSPYIVSANPNHSASKSDEKAEKIKNLFNEAHTTGVLVIQQGQ TQQSYGNDLARASTEYVPASTFKMLNALIGLEHHKATTTEVFKWDGQKRLFPEWEK DMTLGDAMKASAIPVYQDLARRIGLELMSKEVKRVGYGNADIGTQVDNFWLVGPLK ITPQQEAQFAYKLANKTLPFSPKVQDEVQSMLFIEEMNGNKIYAKSGWGWDVDPQV GWLTGWVVQPQGNIVAFSLNLEMKKGIPSSVRKEITYKSLEQLGIL SEQ ID No. 424: MNIKALLLITSAIFISACSPYIVTANPNHSASKSDDKAEKIKNLFNEAHTTGVLVIHQGQ TQQSYGNDLARASTEYVPASTFKMLNALIGLEHHKATTTEVFKWDGEKRLFPEWEK NMTLGDAMKASAIPVYQDLARRIGLELMSKEVKRVGYGNADIGTQVDNFWLVGPLK ITPQQEAQFAYKLANKTLPFSQKVQDEVQSMLFIEEKNGNKIYAKSGWGWDVNPQV GWLTGWVVQPQGNIVAFPLNLEMKKGIPSSVRKEITYKSLEQLGIL SEQ ID No. 425: MNIKALLLITSAIFISACSPYIVTANPNHSASKSDVKAEKIKNLFNEAHTTGVLVIQQGQ TQQSYGNDLARASTEYVPASTFKMLNALIGLEHHKATTTEVFKWDGKKRLFPEWEK DMTLGDAMKASAIPVYQDLARRIGLELMSKEVKRVGYGNADIGTQVDNFWLVGPLK ITPQQEAQFAYKLANKTLPFSQKVQDEVQSMLFIEEKNGNKIYAKSGWGGDVNPQV GWLTGWVVQPQGNIVAFSLNLEMKKGIPSSVRKEITYKSLEQLGIL SEQ ID No. 426: MNIKALLLITSAIFISACSPYIVTANPNHSASKSDVKAEKIKNLFNEAHTTGVLVIQQGQ TQQSYGNDLARASTEYVPASTFKMLNALIGLEHHKATTTEVFKWDGKKRLFPEWEK DMTLGDAMKASAILVYQDLARRIGLELMSKEVKRVGYGNADIGTQVDNFWLVGPLKI TPQQEAQFAYKLANKTLPFSQKVQDEVQSMLFIEEKNGNKIYAKSGWGWDVNPQV GWLTGWVVQPQGNIVAFSLNLEMKKGIPSSVRKEITYKSLEQLGIL SEQ ID No. 427: MNIKALLLITSAIFISACSPYIVTANPNHSASKSDVKAEKIKNLFNEAHTTGVLVIQQGQ TQQSYGNDLARASTEYVPASTFKMLNALIGLEHHKATTTEVFKWDGKKRLFPEWEK DMTLGDAMKASAIPVYQDLARRIGLELMSKEVKRVGYGNADIGTQVDNFWVVGPLK ITPQQEAQFAYKLANKTLPFSQKVQDEVQSMLFIEEKNGNKIYAKSGWGWDVNPQV GWLTGWVVQPQGNIVAFSLNLEMKKGIPSSVRKEITYKSLEQLGIL SEQ ID No. 428: MNIKALLLITSAIFISACSPYIVTANPNHSASKSDEKAEKIKNLFNEAHTTGVLVIQQGQ TQQSYGNDLARASTEYVPASTFKMLNALIGLEHHKTTTTEVFKWDGQKRLFPEWEK DMTLGDAMKASAIPVYQDLARRIGLELMSKEVKRVGYGNADIGTQVDNFWWGPLK ITPQQEAQFAYKLANKTLPFSPKVQDEVQSMLFIEEKNGNKIYAKSGWGWDVDPQV GWLTGWVVQPQGNIVAFSLNLEMKKGIPSSVRKEITYKSLEQLGIL SEQ ID No. 429: MSKKNFILIFIFVILISCKNTEKISNETTLIDNIFTNSNAEGTLVIYNLNDDKYIIHNKERAE QRFYPASTFKIYNSLIGLNEKAVKDVDEVFYKYNGEKVFLESWAKDSNLRYAIKNSQ VPAYKELARRIGLKKMKENIEKLDFGNKSIGDSVDTFWLEGPLEISAMEQVKLLTKLA QNELPYPIEIQKAVSDITILEQTYNYTLHGKTGLADSKNMTTEPIGWFVGWLEENDNI YVFALNIDNINSDDLAKRINIVKESLKALNLLK SEQ ID No. 430: MSKKNFILIFIFVILTSCKNTEKISNETTLIDNIFTNSNAEGTLVIYNLNDDKYIIHNKERA EQRFYPASTFKIYNSLIGLNEKAVKDVDEVFYKYNGEKVFLESWAKDSNLRYAIKNS QVPAYKELARRIGLKKMKENIEKLDFGNKSIGDSVDTFWLEGPLEISAMEQIKLLTKL AQNELPYPIEIQKAVSDITILEQTYNYTLHGKTGLADSKNMTTEPIGWFVGWLEENDN IYVFALNIDNINSDDLAKRINIVKESLKALNLLK SEQ ID No. 431: LLITSAIFISACSPYIVSANPNHSASKSDDKAEKIKNLFNEAHTTGVLVIQQGQTQQSY GNDLARASTEYVPASTFKMLNALIGLEHHKATTTEVFKWDGQKRLFPEWEKNMTLG DAMKASAIPVYQDLARRIGLELMSNEVKRVGYGNADIGTQVDNFWLVGPLKITPQQ EAQFAYKLANKTLPFSQKVQDEVQSMLFIEEKNGNKIYAKSGWGWDVDPQVGWLT GWVVQPQGNIVAFSLNLEMKKGIPSSVRKEITYKSL SEQ ID No. 432: LLITSAIFISACSPYIVSANPNHSASKSDEKAEKIKNLFNEAHTTGVLVIQQGQTQQSY GNDLARASTEYVPASTFKMLNALIGLEHHKATTTEVFKWDGQKRLFPEWEKNMTLG DAMKASAIPVYQDLARRIGLELMSNEVKRVGYGNADIGTQVDNFWLVGPLKITPQQ EAQFAYKLANKTLPFSQKVQDEVQSMLFIEEKNGNKIYAKSGWGWDVNPQVGWLT EWVVQPQGNIVAFSLNLEMKKGIPSSVRKEITYKSL SEQ ID No. 433: MTVRRLSCALGAALSLSALGGGPVQAAVLCTVVADAADGRILFQQGTQQACAERYT PASTFKLAIALMGADAGILQGPHEPVWNYQPAYPDWGGDAWRQPTDPARWIKYSV VWYSQLTAKALGQDRFQRYTSAFGYGNADVSGEPGKHNGTDGAWIISSLRISPLEQ LAFLRKLVNRQLPVKAAAYELAENLFEAGQADGWRLYGKTGTGSPGSNGVYTAAN AYGWFVGWARKDGRQLVYARLLQDERATRPNAGLRARDELVRDWPAMAGAWRP SEQ ID No. 434: MNIKALLLITSAIFISACSPYIVSANPNHSASKSDEKAEKIKNLFNEAHTTGVLVIQQGQ TQQSYGNVLARASTEYVPASTFKMLNALIGLEHHKATTTEVFKWDGQKRLFPEWEK NMTLGDAMKASAIPVYQDLARRIGLELMSNEVKRVGYGNADIGTQVDNFWLVGPLK ITPQQEAQFAYKLANKTLPFSQEVQDEVQSMLFIEEKNGNKIYAKSGWGWDVNPQV GWLTGWVVQPQGNIVAFSLNLEMKKGIPSSVRKEITYKSLEQLGIL SEQ ID No. 435: MKTFAAYVIIACLSSTALAGSITENTSWNKEFSAEAVNGVFVLCKSSSKSCATNDLAR ASKEYLPASTFKIPSAIIGLETGVIKNEHQVFKWDGKPRAMKQWERDLTLRGAIQVS AVPVFQQIAREVGEVRMQKYLKKFSYGNQNISGGIDKFWLEDQLRISAVNQVEFLES LYLNKLSASKENQLIVKEALVTEAAPEYLVHSKTGFSGVGTESNPGVAWWVGWVEK ETEVYFFAFNMDIDNESKLPLRKSIPTKIMESEGIIGG SEQ ID No. 436: MNIKTLLLITSAIFISACSPYIVTANPNHSASKSDVKAEKIKNLFNEAHTTGVLVIQQGQ TQQSYGNDLARASTEYVPASTFKMLNALIGLEHHKATTTEVFKWDGKKRLFPEWEK DMTLGDAMKASAIPVYQDLARRIGLELMSKEVKRVGYGNADIGTQVDNFWVVGPLK ITPQQEAQFAYKLANKTLPFSQKVQDEVQSMLFIEEKNGNKIYAKSGWGWDVNPQV GWLTGWVVQPQGNIVAFSLNLEMKKGIPSSVRKEITYKSLEQLGIL SEQ ID No. 437: MNIKALLLITSAIFISACSPYIVTTNPNHSASKSDEKAEKIKNLFNEAHTTGVLVIQQGQ TQQSYGNDLARASTEYVPASTFKMLNALIGLEHHKATTTEVFKWDGKKRLFPEWEK DMTLGDAMKASAIPVYQDLARRIGLELMSKEVKRVGYGNTDIGTQVDNFWLVGPLKI TPQQEAQFAYKLANKTLPFSQKVQDEVQSMLFIEEKNGNKIYAKSGWGWDVDPQV GWLTGWVVQPQGNIVAFSLNLEMKKGIPSSVRKEITYKSLEQLGIL SEQ ID No. 438: MNIKALLLITSAIFISACSPYIVTANPNHSASKSDVKAEKIKNLFNEAHTTGVLVIQQGQ TQQSYGNDLARASTEYVPASTFKMLNALIGLEHHKATTTEVFKWDGKKRLFPEWEK DMTLGDAMKASAVPVYQDLARRIGLELMSKEVKRVGYGNADIGTQVDNFWLVGPL KITPQQEAQFAYKLANKTLPFSQKVQDEVQSMLFIEEKNGNKIYAKSGWGWDVNQ QVGWLTGWVVQPQGNIVAFSLNLEMKKGIPSSVRKEITYKSLEQLGIL SEQ ID No. 439: MNIKTLLLITSAIFISACSPYIVTANPNHSASKSDEKAEKIKNLFNEVHTTGVLVIQQGQ TQQSYGNDLARASTEYVPASTFKMLNALIGLEHHKATTTEVFKWDGQKRLFPEWEK DMTLGDAMKASAIPVYQDLARRIGLELMSKEVKRVGYGNADIGTQVDNFWLVGPLK ITPQQEAQFAYKLANKTLPFSPKVQDEVQSMLFIEEKNGNKIYAKSGWGWDVDPQV GWLTGWVVQPQGNIVAFSLNLEMKKGIPSSVRKEMTYKSLEQLGIL SEQ ID No. 440: MNKYFTCYVVASLFFSGCTVQHNLINETQSQIVQGHNQVIHQYFDEKNTSGVLVIQT DKKINLYGNALSRANTEYVPASTFKMLNALIGLENQKTDINEIFKWKGEKRSFTTWE KDMTLGEAMKLSAVPVYQELARRIGLDLMQKEVERIDFGNAEIGQQVDNFWLIGPLK VTPIQEVEFVSQLAHTQLPFSEKVQANVKNMLLLEENNGYKIFGKTGWAMDIKPQV GWLTGWVEQPDGKIVAFALNMEMRSEMPASIRNELLMKSLKQLNII SEQ ID No. 441: MNKYFTCYVVASLFLSGCTVQHNLINETPSQIVQGHNQVIHQYFDEKNTSGVLVIQT DKKINLYGNALSRANTEYVPASTFKMLNALIGLENQKTDINEIFKWKGEKRSFTAWE KDMTLGEAMKLSAVPVYQELARRIGLDLMQKEVKRIGFGNAEIGQQVDNFWLVGPL KVTPIQEVEFVSQLAHTQLPFSEKVQANVKNMLLLEESNGYKIFGKTGWAAMDIKPQ VGWLTGWVEQPDGKIVAFALNMEMRSEMPASIRNELLMKSLKQLNII SEQ ID No. 442: MKTFAAYVITACLSSTALASSITENTSWNKEFSAEAVNGVFVLCKSSSKSCATNNLA RASKEYLPASTFKIPNAIIGLETGVIKNEHQVFKWDGKPRAMKQWERDLSLRGAIQV SAVPVFQQIAREVGEVRMQKYLKKFSYGNQNISGGIDKFLLEGQLRISAVNQVEFLE SLFLNKLSASKENQLIVKEALVTEAAPEYLVHSKTGFSGVGTESNPGVAWWVGWVE KGTEVYFFAFNMDIDNENKLPLRKSIPTKIMASEGIIGG SEQ ID No. 443: MAIRIFAILFSIFSLATFAHAQEGTLERSDWRKFFSEFQAKGTIVVADERQADRAMLV FDPVRSKKRYSPASTFKIPHTLFALDAGAVRDEFQIFRWDGVNRGFAGHNQDQDLR SAMRNSTVWVYELFAKEIGDDKARRYLKKIDYGDADPSTSNGDYWIEGSLAISAQE QIAFLRKLYRNELPFRVEHQRLVKDLMIVEAGRNWILRAKTGWEGRMGWWVGWVE WPTGSVFFALNIDTPNRMDDLFKREAIVRAILRSIEALPPNPAVNSDAAR SEQ ID No. 444: MNIKALLLITSAIFISACSPYIVTANPNHSASKSDKKAEKIKNLFNEAHTTGVLVIQQGQ TQQSYGNDLARASTEYVPASTFKMLNALIGLEHHKASTTEVFKWNGQKRLFPEWEK DMTLGDAMKASAIPVYQDLARRIGLELMSNEVKRVGYGNADIGTQVDNFWLVGPLK ITPQQEAQFAYKLANKTLPFSQKVQDEVKSMLFIEEKNGNKIYAKSGWGWDVDPQV GWLTGWVVQPQGNIVAFSLNLEMKKGIPSSVRKEITYKSLEQLGIL SEQ ID No. 445: MNIKALLLITSAIFISACSPYIVSANPNHSASKSDEKAEKIKNLFNEAHTTGVLVIQQGQ TQQSYGNDLARASTEYVPASTFKMLNALIGLEHHKATTTEVFKWDGQKRLFPEWEK NMTLGDAMKASAIPVYQDLARRIGLELMSNEVKHVGYGNADIGTQVDNFWLVGPLK ITPQQEAQFAYKLANKTLPFSPKVQDEVQSMLFIEEKNGNKIYAKSGWGWDVNPQV GWLTGWVVQPQGNIVAFSLNLEMKKGIPSSVRKEITYKSLEQLGIL SEQ ID No. 446: MNIKALLLITSAIFISACSPYIVSANPNHSASKSDEKAEKIKNLFNEAHTTGVLVIQQGQ TQQSYGNDLARASTEYVPASTFKMLNALIGLEHHKATTTEVFKWDGQKRLFPEWEK NMTLGDAMKASAIPVYQDLARRIGLELMSNEVKHVGYGNADIGTQVDNFWLVGPLK ITPQQEAQFAYKLANKTLPFSQKVQDEVQSMLFIEEKNGNKIYAKSGWGWDVNPQV GWLTGWVVQPQGNIVAFSLNLEMKKGIPSSVRKEITYKSLEQLGIL SEQ ID No. 447: MKKFILPILSISTLLSVSACSSIQTKFEDTFHTSNQQHEKAIKSYFDEAQTQGVIIIKKG KNISTYGNNLTRAHTEYVPASTFKMLNALIGLENHKATTTEIFKWDGKKRSYPMWEK DMTLGDAMALSAVPVYQELARRTGLDLMQKEVKRVGFGNMNIGTQVDNFWLVGPL KITPIQEVNFADDFANNRLPFKLETQEEVKKMLLIKEFNGSKIYAKSGWGMDVTPQV GWLTGWVEKSNGEKVAFSLNIEMKQGMPGSIRNEITYKSLENLGII SEQ ID No. 448: MNIKALLLITSAIFISACSPYIVSANPNHSASKSDEKAEKIKNLFNEAHTTGVLVIQQGQ TQQSYGNDLARASTEYVPASTFKMLNALIGLEHHKATTTEVFKWDGQKRLFPEWEK NMTLGDAMKASAIPVYQDLARRIGLELMSNEVKRVGYGNADIGTQVDNFWLVGPLK ITPQQEAQFAYKLANKTLPFSQEVQDEVQSILFIEEKNGNKIYAKSGWGWDVNPQV GWLTGWVVQPQGNIVAFSLNLEMKKGIPSSVRKEITYKSLEQLGIL SEQ ID No. 449: MKKFILPIFSISILVSLSACSSIKTKSEDNFHISSQQHEKAIKSYFDEAQTQGVIIIKEGK NLSTYGNALARANKEYVPASTFKMLNALIGLENHKATTNEIFKWDGKKRTYPMWEK DMTLGEAMALSAVPVYQELARRTGLELMQKEVKRVNFGNTNIGTQVDNFWLVGPL KITPVQEVNFADDLAHNRLPFKLETQEEVKKMLLIKEVNGSKIYAKSGWGMGVTSQV GWLTGWVEQANGKKIPFSLNLEMKEGMSGSIRNEITYKSLENLGII SEQ ID No. 450: MRVLALSAVFLVASIIGMPAVAKEWQENKSWNAHFTEHKSQGVVVLWNENKQQGF TNNLKRANQAFLPASTFKIPNSLIALDLGVVKDEHQVFKWDGQTRDIATWNRDHNLI TAMKYSVVPVYQEFARQIGEARMSKMLHAFDYGNEDISGNVDSFWLDGGIRISATE QISFLRKLYHNKLHVSERSQRIVKQAMLTEANGDYIIRAKTGYSARIEPKIGWWVGW VELDDNVWFFAMNMDMPTSDGLGLRQAITKEVLKQEKIIP SEQ ID No. 451: MNIKALLLITSAIFISACSPYIVTANPNHSASKSDVKAEKIKNLFNEAHTTGVLVIQQGQ TQQSYGNDLARASTEYVPASTFKMLNALIGLEHHKATTTEVFKWDGKKRLFPEWEK DMTLGDAMKASAVPVYQDLARRIGLELMSKEVKRVGYGNADIGTQVDNFWLVGPL KITPQQEAQFAYKLANKTLPFSQKVQDEVQSMLFIEEKNGNKIYAKSGWGLDVNPQ VGWLTGWVVQPQGNIVAFSLNLEMKKGIPSSVRKEITYKSLEQLGIL SEQ ID No. 452: MNIKALLLITSAIFISACSPYIVTANPNHSASKSDVKAEKIKNLFNEAHTTGVLVIQQGQ TQQSYGNDLARASTEYVPASTFKMLNALIGLEHHKATTTEVFKWDGKKRLFPEWEK DMTLGDAMKASAVPVYQDLARRIGLELMSKEVKRVGYGNADIGTQVDNFWLVGPL KITPQQEAQFAYKLANKTLPFSQKVQDEVQSMLFIEEKNGNKIYAKSGWGLDVNLQ VGWLTGWVVQPQGNIVAFSLNLEMKKGIPSSVRKEITYKSLEQLGIL SEQ ID No. 453: MNIKALLLITSAIFISACSPYIVTANPNHSASKSDVKAEKIKNLFNEAHTTGVLVIQQGQ TQQSYGNDLARASTEYVPASTFKMLNALIGLEHHKATTTEVFKWDGKKRLFPEWEK DMTLGDAMKASAIPVYQDLARRIGLELMSKEVKRVGYGNADIGTQVDNFWVVGPLK ITPQQEAQFAYKLANKTLPFSQKVQDEVQSMLFIEEKNGNKIYAKSGWGWDVNPQV GWLTGWVVQPQGNIVAFSLNLEMKKGIPSSVRKEITYKSLEKLGIL SEQ ID No. 454: MNIKALLLITSAIFISACSPYIVTANPNHSASKSDVKAEKIRNLFNEAHTTGVLVIQQGQ TQQSYGNDLARASTEYVPASTFKMLNALIGLEHHKATTTEVFKWDGKKRLFPEWEK DMTLGDAMKASAIPVYQDLARRIGLELMSKEVKRVGYGNADIGTQVDNFWVVGPLK ITPQQEAQFAYKLANKTLPFSQKVQDEVQSMLFIEEKNGNKIYAKSGWGWDVNPQV GWLTGWVVQPQGNIVAFSLNLEMKKGIPSSVRKEITYKSLEQLGIL SEQ ID No. 455: MNIKALLLITSAIFISACSPYIVTANPNHSASKSDVKAEKIKNLFNEAHTTGVLVIQQGQ TQQSYGNDLARASTEYVPASTFKMLNALIGLEHHKATTTEVFKWDSKKRLFPEWEK DMTLGDAMKASAIPVYQDLARRIGLELMSKEVKRVGYGNADIGTQVDNFWVVGPLK ITPQQEAQFAYKLANKTLPFSQKVQDEVQSMLFIEEKNGNKIYAKSGWGWDVNPQV GWLTGWVVQPQGNIVAFSLNLEMKKGIPSSVRKEITYKSLEQLGIL SEQ ID No. 456: MNIKALLLITSAIFISACSPYIVTANPNHSASKSDVKAEKIKNLFNEAHTTGVLVIQQGQ TQQSYGNDLARASTEYVPASTFKMLNALIGLEHHKATTTEVFKWDGKKRLFPEWEK DMTLGDAMKASAIPVYQDLARRIGLELMSKEVKRVGYGNADIGTQVDNFWVVGPLK ITPQQEAQFAYKLANKTLPFSQKVQDGVQSMLFIEEKNGNKIYAKSGWGWDVNPQ VGWLTGWVVQPQGNIVAFSLNLEMKKGIPSSVRKEITYKSLEQLGIL SEQ ID No. 457: MNIKALLLITSAIFISACSPYIVTANPNHSASKSDVKAEKIKNLFNEAHTTGVLVIQQGQ TQQSYGNDLARASTEYVPASTFKMLNALIGLEHHKATTTEVFKWDSKKRLFPEWEK DMTLGDAMKASAILVYQDLARRIGLELMSKEVKRVGYGNADIGTQVDNFWLVGPLKI ITPQQEAQFAYKLANKTLPFSQKVQDEVQSMLFIEEKNGNKIYAKSGWGWDVNPQV GWLTGWVVQPQGNIVAFSLNLEMKKGIPSSVRKEITYKSLEQLGIL SEQ ID No. 458: MKLLKILSLVCLSISIGACAEHSMSRAKTSTIPQVNNSIIDQNVQALFNEISADAVFVTY DGQNIKKYGTHLDRAKTAYIPASTFKIANALIGLENHKATSTEIFKWDGKPRFLKAWD KDFTLGEAMQASTVPVYQELARRIGPSLMQSELQRIGYGNMQIGTEVDQFWLKGPL TITPIQEVKFVYDLAQGQLPFKPEVQQQVKEMLYVERRGENRLYAKSGWGMAVDP QVGWYVGFVEKADGQVVAFALNMQMKAGDDIALRKQLSLDVLDKLGVFHYL SEQ ID No. 459: MNKYFTCYVVASLFLSGCTVQHNLINETPSQIVQGHNQVIHQYFDEKNTSGVLVIQT DKKINLYGNALSRANTEYVPASTFKMLNALIGLENQKTDINEIFKWKGEKRSFTAWE KDMTLGEAMKLSAVPVYQELARRIGLDLMQKEVKRIGFGNAEIGQQVDNFWLVGPL KVTPIQEVEFVSQLAHTQLPFSEKVQANVKNMLLLEESNGYKIFGKTGWAMDVKPQ VGWLTGWVEQPDGKIVAFALNMEMRSEMPASIRNELLMKSLKQLNII SEQ ID No. 460: MNKYFTCYVVASLFLSGCTVQHNLINETPSQIVQGHNQVIHQYFDEKNTSGALVIQT DKKINLYGNALSRANTEYVPASTFKMLNALIGLENQKTDINEIFKWKGEKRSFTAWE KDMTLGEAMKLSAVPVYQELARRIGLDLMQKEVKRIGFGNAEIGQQVDNFWLVGPL KVTPIQEVEFVSQLAHTQLPFSEKVQANVKNMLLLEESNGYKIFGKTGWAMDIKPQV GWLTGWVEQPDGKIVAFALNMEMRSEMPASIRNELLMKSLKQLNII SEQ ID No. 461: MNKYFTCYVVASLFLSGCTVQHNLINETPSQIVQGHNQVIHQYFDEKNTSGVLVIQT DKKINLYGNALSRANTEYVPASTFKMLNALIGLENQKTDINEIFKWKGEKRSFTAWE KDMTLGEAMKLSAVPVYQELARRIGLDLMQKEVKRIGFGNAEIGQQVDNFWLVGPL KVTPIQEVEFVSQLAHTQLPFSEKVQANVKNMLLLEESNGYKIFGKTGWAMDIKPQV GWLTGWVEQPDGKIVAFALNMEMRSEMPASIRNELMMKSLKQLNII SEQ ID No. 462: MNKYFTCYVVASLFLSGCTVQHNLINETPSQIVQGHNQVIHQYFDEKNTSGVLVIQT DKKINLYGNALSRANTEYVPASTFKMLNALIGLENQKTDINEIFKWKGEKRSFTAWE KDMTLGEAMKLSAVPVYQELARRIGLDLMQKEVKRIGFGNAEIGQQVDNFWLVGPL KVTPIQEVEFVSQLAHTQLPFSEKVQANVKNMLLLEESNGYKIFGKTGWAMDIKPQV GWLAGWVEQPDGKIVAFALNMEMRSEMPASIRNELLMKSLKQLNII SEQ ID No. 463: MNKYFTCYVVASLFLSGCTVQHNLINETPSQIVQGHNQVIHQYFDERNTSGVLVIQT DKKINLYGNALSRANTEYVPASTFKMLNALIGLENQKTDINEIFKWKGEKRSFTAWE KDMTLGEAMKLSAVPVYQELARRIGLDLMQKEVKRIGFGNAEIGQQVDNFWLVGPL KVTPIQEVEFVSQLAHTQLPFSEKVQANVKNMLLLEESNGYKIFGKTGWAMDIKPQV GWLTGWVEQPDGKIVAFALNMEMRSEMPASIRNELLMKSLKQLNII SEQ ID No. 464: MNKYFTCYVVASLFLSGCTVQHNLINETPSQIVQGHNQVIHQYFDEKNTSGVLVIQT DKKINLYGNALSRANTEYVPASTFKMLNALIGLENQKTDINEIFKWKGEKRSFTAWE KDMTLGEAMKLSAVPVYQELARRIGLDLMQKEVKRIGFGNAEIGQQVDNFWLVGPL KVTPIQEVEFVSQLAHTQLPFSEKVQANVKNMLLLEKSNGYKIFGKTGWAMDIKPQV GWLTGWVEQPDGKIVAFALNMEMRSEMPASIRNELLMKSLKQLNII SEQ ID No. 465: MNKYFTCYVVASLFLSGCTVQHNLINETPSQIVQGHNQVIHQYFDEKNTSGVLVIQT DKKINLYGNALSRANTEYVPASTFKMLNALIGLENQKTDINEIFKWKGEKRSFTAWE KDMTLGEAMKLSAVPVYQELARRIGLDLMQKEVKRIGFGNAEIGQQVDNFWLVGPL KVTPIQEVEFVSQLAHTQLPFSEKVQANVKNMLLLEESNGYKIFGKTGWAMDIKPQV GWLTGWVEQPDGKIVAFALNMEMRSEMPASTRNELLMKSLKQLNII SEQ ID No. 466: MKKFILPIFSISILLSLSACSSIQTKFEDTFHISNQKHEKAIKSYFDEAQTQGVIIIKEGKN ISSYGNNLVRAHTEYVPASTFKMLNALIGLENHKATTNEIFKWDGKKRSYPMWEKD MTLGEAMALSAVPVYQDLARRIGLNLMQKEVKRVGFGNMNIGTQVDNFWLIGPLKI TPIQEVNFADDLANNRLPFKLETQEEVKKMLLIKEVNGSKIYAKSGWGMDVSPQVG WLTGWVEKSNGEKVSFSLNIEMKQGMSGSIRNEITYKSLENLGII SEQ ID No. 467: MNIKALLLITSAIFISACSPYIVTANPNHSASKSDEKAEKIKNLFNEAHTTGVLVIQQGQ TQQSYGNDLARASTEYVPASTFKMLNALIGLEHHKATTTEVFKWDGQKRLFPEWEK DMTLGDAMKASAIAVYQDLARRIGLELMSKEVKRVGYGNADIGTQVDNFWLVGPLK ITPQQEAQFAYKLANKTLPFSPKVQDEVQSMLFIEEKNGNKIYAKSGWGWDVDPQV GWLTGWVVQPQGNIVAFSLNLEMKKGIPSSVRKEITYKSLEQLGIL SEQ ID No. 468: MNIKALLLITSAIFISACSPYIVTANPNHSASKSDEKAEKIKNLFNEAHTTGVLVIQQGQ TQQSYGNDLARASTEYVPASTFKMLNALIGLEHHKATTTEVFKWDGQKRLFPEWEK DMTLGDAIKASAIPVYQDLARRIGLELMSKEVKRVGYGNADIGTQVDNFWLVGPLKI TPQQEAQFAYKLANKTLPFSQKVQDEVQSMLFIEEKNGNKIYAKSGWGWDVDPQV GWLTGWVVQPQGNIVAFSLNLEMKKGIPSSVRKEITYKSLEQLGIL SEQ ID No. 469: MKILIFLPLLSCLGLTACSLPVSSLPSQSISTQAIASLFDQAQSSGVLVIQRDQQVQVY GNDLNRANTEYVPASTFKMLNALIGLQHGKATTNEIFKWDGKKRSFTAWEKDMTLG QAMQASAVPVYQELARRIGLELMQQEVQRIQFGNQQIGQQVDNFWLVGPLKVTPK QEVQFVSALAREQLAFDPQVQQQVKAMLFLQERKAYRLYVKSGWGMDVEPQVGW LTGWVETPQAEIVAFSLNMQMQNGIDPAIRLEILQQALAELGLYPKAEG SEQ ID No. 470: MHKHMSKLFIAFLAFLLSVPAAAEDQTLAELFAQQGIDGTIVISSLHNGKTFIHNDPRA KQRFSTASTFKILNTLISLEEKAISGKDDVLKWDGHIYDFPDWNRDQTLESAFKVSCV WCYQALARQVGAEKYRNYLRKSVYGELREPFEETTFWLDGSLQISAIEQVNFLKKV HLRTLPFSASSYETLRQIMLIEQTPAFTLRAKTGWATRVKPQVGWYVGHVETPTDV WFFATNIEVRDEKDLPLRQKLTRKALQAKGIIE SEQ ID No. 471: MKTFAAYVITACLSSTALASSITENTSWNKEFSAEAVNGVFVLCKSSSKSCATNNLA RASKEYLPASTFKIPNAIIGLETGVIKNEHQVFKWDGKPRAMKQWERDLSLRGAIQV SAVPVFQQIAREVGEVRMQKYLKKFSYGNQNISGGTDKFWLEDQLRISAVNQVEFL ESLFLNKLSASKENQLIVKEALVTEAAPEYLVHSKTGFSGVGTESNPGVAWWVGWV EKGTEVYFFAFNMDIDNENKLPLRKSIPTKIMASEGIIGG SEQ ID No. 472: MNIKALLLITSAIFISACSPYIVTANPNHSASKSDEKAEKIKNLFNEAHTTGVLVIQQGQ TQQSYGNDLARASTEYVPASTFKMLNALIGLEHHKATTTEVFKWDGKKRLFPEWEK DMTLGDAMKASAILVYQDLARRIGLELMSKEVKRVGYGNADIGTQVDNFWLVGPLKI TPQQEAQFAYKLANKTLPFSQKVQDEVQSMLFIEEKNGNKIYAKSGWGLDVDPQV GWLTGWVVQPQGNIVAFSLNLEMKKGIPSSVRKEITYKSLEQLGIL SEQ ID No. 473: MNIKALLLITSAIFISACSPYIVTANPNHSASKSDVKAEKIKNLFNEAHTTGVLVIQQGQ TQQSYGNDLARASTEYVPASTFKMLNALIGLEHHKATTTEVFKWDGKKRLFPEWEK DMTLGDAMKASAIQVYQDLARRIGLELMSKEVKRVGYGNADIGTQVDNFWVVGPLK ITPQQEAQFAYKLANKTLPFSQKVQDEVQSMLFIEEKNGNKIYAKSGWGWDVNPQV GWLTGWVVQPQGNIVAFSLNLEMKKGIPSSVRKEITYKSLEQLGIL SEQ ID No. 474: MNIKALLLITSAIFISACSPYIVTANPNHSASKSDVKAEKIKNLFNEAHTTGVLVIQQGQ TQQSYGNDLARASTEYVPASTFKMLNALIGLEHHKATTTEVFKWDGKKRLFPEWEK DMTLGDAMKASAMPVYQDLARRIGLELMSKEVKRVGYGNADIGTQVDNFWLVGPL KITPQQEAQFAYKLANKTLPFSQKVQDEVQSMLFIEEKNGNKIYAKSGWGWDVNPQ VGWLTGWVVQPQGNIVAFSLNLEMKKGIPSSVRKEITYKSLEQLGIL SEQ ID No. 475: MNIKALLLITSAIFISACSPYIVTANPNHSASKSDEKAEKIKNLFNEVHTTGVLVIQQGQ TQQSYGNDLARASTEYVPASTFKMLNALIGLEHHKATTTEVFKWDGKKRLFPEWEK NMTLGDAMKASAIPVYQDLARRIGLELMSNEVKRVGYGNADIGTQVDNFWLVGPLK ITPQQEAQFAYKLANKTLPFSQKVQDEVQSMLFIEEKNGNKIYAKSGWGWDVDPQV GWLTGWVVQPQGNIVAFSLNLEMKKGIPSSVRKEITYKSLEQLGIL SEQ ID No. 476: MRVLALSAVFLVASIIGMPAVAKEWQENKSWNAHFTEHKSQGVVVLWNENKQQGF TNNLKRANQAFLPASTFKIPNSLIALDLGVVKDEHQVFKWDGQTRDIATWNRDHNLI TAMKYSVVPVYQEFARQIGEARMSKMLHAFDYGNEDISGNVDSFWLDGGIRISATE QISFLRKLYHNKLHVSERSQRIVKQAMLTEANGDYIIRAKTGYDTKIGWWVGWVELD DNVWFFAMNMDMPTSDGLGLRQAITKEVLKQEKIIP SEQ ID No. 477: MSKKNFILIFIFVILISCKNTEKTSNETTLIDNIFTNSNAEGTLVIYNLNDDKYIIHNKERA EQRFYPASTFKIYNSLIGLNEKAVKDVDEVFYKYNGEKVFLESWAKDSNLRYAIKNS QVPAYKELARRIGLEKMKENIEKLDFGNKNIGDSVDTFWLEGPLEISAMEQVKLLTKL AQNELPYPIEIQKAVSDITILEQTDNYTLHGKTGLADSENMTTEPIGWLVGWLEENNN IYVFALNIDNINSDDLAKRINIVKESLKALNLLK SEQ ID No. 478: MNIKALFLITSAIFISACSPYIVTANPNHSASKSDVKAEKIKNLFNEAHTTGVLVIQQGQ TQQSYGNDLARASTEYVPASTFKMLNALIGLEHHKATTTEVFKWDGKKRLFPEWEK DMTLGDAMKASAIPVYQDLARRIGLELMSKEVKRVGYGNADIGTQVDNFWVVGPLK ITPQQEAQFAYKLANKTLPFSQKVQDEVQSMLFIEEKNGNKIYAKSGWGWDVNPQV GWLTGWVVQPQGNIVAFSLNLEMKKGIPSSVRKEITYKSLEQLGIL SEQ ID No. 479: MNIKALFLITSAIFISACSPYIVTANPNHSASKSDVKAEKIKNLFNEAHTTGVLVIQQGQ TQQSYGNDLARASTEYVPASTFKMLNALIGLEHHKATTTEVFKWDGKKRLFPEWEK DMTLGDAMKASAIPVYQDLARRIGLELMSKEVKRVGYGNADIGTQVDNFWVVGPLK ITPQQEAQFAYKLANKTLPSSQKVQDEVQSMLFIEEKNGNKMYAKSGWGWDVNPQ VGWLTGWVVQPQGNIVAFSLNLEMKKGIPSSVRKEITYKSLEQLGIL SEQ ID No. 480: MNIKALFLITSAIFISACSPYIVTANPNHSASKSDVKAEKIKNLFNEAHTTGVLVIQQGQ TQQSYGNDLARASTEYVPASTFKMLNALIGLEHHKATTTEVFKWDGKKRLFPEWEK DMTLGDAMKASAIPVYQDLARRIGLELMSKEVKRVGYGNADIGTQVDNFWVVGPLK ITPQQEAQFAYKLANKTLPFSQKVQDEVQSMLFIEEKNGNKIYAKSGWGWDVNPQV GWLTGWVVQPQGNIVAFSLNLEMKKGIPSSVRKEIAYKSLEQLGIL SEQ ID No. 481: MAIRIFAILFSIFSLATFAHAQEGTLERSDWRKFFSEFQAKGTIVVADERQADRAMLV FDPVRSKKRYSPASTFKIPHTLFALDAGAVRDEFQIFRWDGVNRGFAGHNQDQDLR SAMRNSTVWVYELFAKEIGDDKARRYLKKIDYGNADPSTSNGDCWIEGSLAISAQE QIAFLRKLYRNELPFRVEHQRLVKDLMIVEAGRNWILRAKTGWEGRMGWWVGWVE WPTGSVFFALNIDTPNRMDDLFKREAIVRAILRSIEALPPNPAVNSDAAR SEQ ID No. 482: MNIKTLLLITSAIFISACSPYIVTANPNHSASKSDEKAEKIKNLFNEVHTTGVLVIQQGQ TQQSYGNDLARASTEYVPASTFKMLNALIGLEHHKATTTEVFKWDGQKRLFPEWEK DMTLGDAMKASAIPVYQDLARRIGLELMSKEVKRVGYGNADIGTQVDNFWVVGPLK ITPQQEAQFAYKLANKTLPFSPKVQDEVQSMLFIEEKNGNKIYAKSGWGWDVDPQV GWLTGWVVQPQGNIVAFSLNLEMKKGIPSSVRKEITYKSLEQLGIL SEQ ID No. 483: MNIKTLLLITSAIFISACSPYIVTANPNHSASKSDEKAEKIKNLFNEVHTTGVLVIQQGQ TQQSYGNDLARASTEYVPASTFKMLNALIGLEYHKATTTEVFKWDGQKRLFPEWEK DMTLGDAMKASAIPVYQDLARRIGLELMSKEVKRVGYGNADIGTQVDNFWLVGPLK ITPQQEAQFAYKLANKTLPFSPKVQDEVQSMLFIEEKNGNKIYAKSGWGWDVNPQV GWLTGWVVQPQGNIVAFSLNLEMKKGIPSSVRKEITYKSLEQLGIL SEQ ID No. 484: MAIRFLTILLSTFFLTSFVHAQEHVVVRSDWKKFFSDLQAEGAIVIADERQAEHALLV FGQERAAKRYSPASTFKLPHTLFALDAGAVRDEFQVFRWDGVKRSFAGHNQDQDL RSAMRNSAVWVYELFAKEIGEDNARRYLKQIDYGNADPSTIKGNYWIDGNLEISAHE QISFLRKLYRNQLPFQVEHQRLVKYLMITEAGRNWILRAKTGWEGRFGWWIGWVE WPTGPVFFALNIDTPNRTDDLFKREAIARAILRSIDALPPN SEQ ID No. 485: MRVLALSAVFLVASIIGMPAVAKEWQENKSWNAHFTEHKSQGVVVLWNENKQQGF TNNLKRANQAFLPASTFKIPNSLIALDLGVVKDEHQVFKWDGQTRDIAAWNRDHDLI TAMKYSVVPVYQEFARQIGEARMSKMLHAFDYGNEDISGNVDSFWLDGGIRISATQ QIAFLRKLYHNKLHVSERSQRIVKQAMLTEANGDYIIRAKTGYSTRIEPKIGWWVGW VELDDNVWFFAMNMDMPTSDGLGLRQAITKEVLKQEKIIP SEQ ID No. 486: MNKYFTCYVVASLFLSGCTVQHNLINETPSQIVQGHNQVIHQYFDEKNTSGVLVIQT DKKINLYGNALSRANTEYVPASTFKMLNALIGLENQKTDINEIFKWKGEKRSFTAWE KDMTLGEAMKLSAVPVYQELARRIGLDLMQKEVKRIGFGNAEIGQQVDNFWLVGPL KVTPIQEVEFVSQLAHTQLPFSEKVQANVKNMLLLEESNGYKIFGKTGWAMDIKSQV GWLTGWVEQPDGKIVAFALNMEMRSEMPASIRNELLMKSLKQLNII SEQ ID No. 487: MNIKALLLITSAIFISACSPYIVTANPNHSASKSDVKAEKIKNLFNEAHTTGVLVIQQGQ TQQSYGNDLARASTEYVPASTFKMLNALIGLEHHKATTTEVFKWDGKKRLFPEWEK DMTLGDAMKASAISVYQDLARRIGLELMSKEVKRVGYGNADIGTQVDNFWLVGPLK ITPQQEAQFAYKLANKTLPFSQKVQDEVQSMLFIEEKNGNKIYAKSGWGWDVNPQV GWLTGWVVQPQGNIVAFSLNLEMKKGIPSSVRKEITYKSLEQLGIL SEQ ID No. 488: MAIRIFAILFSIFSLATFAHAQEGTLERSDWRKFFSEFQAKGTIVVADERQADRAMLV FDPVRSKKRYSPASTFKIPHTLFALDAGAVRDEFQIFRWDGVNRGFAGHNQDQDLR SAMRNSTVWVYELFAKEIGDDKARRYLKKIDYGNADPSTSNGDYWIEGSLAISAQE QIAFLRKLYRNELPFRVEHQRLVKDLMIVEAGRNWILRAKTGWEGRMGWWVGWVE WPTGSVFFALNIDTPNRMDDLFKREAIVRAILRSIEALPPNPAVNSDAAR SEQ ID No. 489: MKTIAAYLVLVFYASTALSESISENLAWNKEFSSESVHGVFVLCKSSSNSCTTNNAA RASTAYIPASTFKIPNALIGLETGAIKDERQVFKWDGKPRAMKQWEKDLKLRGAIQV SAVPVFQQIAREVGEIRMQKYLNLFSYGNANIGGGIDKFWLEGQLRISAFNQVKFLE SLYLNNLPASKANQLIVKEAIVTEATPEYIVHSKTGYSGVGTESSPGVAWWVGWVE KGTEVYFFAFNMDIDNESKLPSRKSISTKIMASEGIIIGG SEQ ID No. 490: MKTFAAYVITACLSSTALASSITENTFWNKEFSAEAVNGVFVLCKSSSKLACATNNLA RASKEYLPASTFKIPNAIIGLETGVIKNEHQIFKWDGKPRAMKQWERDLSLRGAIQVS AVPVFQQIAREVGEVRMQKYLKKFSYGNQNISGGIDKFWLEGQLRISAVNQVEFLE SLFLNKLSASKENQLIVKEALVTEAPEYLVHSKTGFSGVGTESNPGVAWWVGWVEK GAEVYFFAFNMDIDNENKLPLRKSIPTKIMASEGIIGG SEQ ID No. 491: MAIRIFAILFSTFVFGTFAHAQEGMRERSDWRKFFSEFQAKGTIVVADERQTDRVILV FDQVRSEKRYSPASTFKIPHTLFALDAGAARDEFQVFRWDGIKRSFAAHNQDQDLR SAMRNSTVWIYELFAKEIGEDKARRYLKQIDYGNADPSTSNGDYWIDGNLAIAAQEQ IAFLRKLYHNELPFRVEHQRLVKDLMIVEAGRNWILRAKTGWEGRMGWWVGWVE WPTGPVFFALNIDTPNRMDDLFKREAIVRAILRSIEALPPNPAVNSDAAR SEQ ID No. 492: MKTFAAYVIIACLSSTALAGSITENTSWNKEFSAEAVNGVFVLCKSSSKSCATNDLAR ASKEYLPASTFKIPNAIIGLETGVIKNEHQVFKWDGKPRAMKQWERDLTLRGAIQVS AVPVFQQIAREVGEVRMQKYLKKFSYGSQNISGGIDKFWLEDQLRISAVNQVEFLES LYLNKLSASKENQLIVKEALVTEAAPEYLVHSKTGFSGVGTESNPGVAWWVGWVEK ETEVYFFAFNMDIDNESKLPLRKSIPTKIMESEGIIGG SEQ ID No. 493 MNKYFTCYVVASLFLSGCTVQHNLINETPSQIVQGHNQVIHQYFDEKNTSGVLVIQT DKKINLYGNALSRANTEYVPASTFKMLNALIGLENQKTDINEIFKWKGEKRSFTAWE KDMTLGEAMKLSAVPVYQELARRIGLDLMQKEVKRIGFGNAEIGQQVDNFWLVGPL KVTPIQEVEFVSQLAHTQLPFSEKVQANVKNMLLLEESNGYKIFGKTGWAMDIKPQV GWLTGWVEQPDGKIVAFALNMEMRSEMPASIRNELLMKSLKQLNII SEQ ID No. 494 MKKLSVLLWLTLFYCGTIWAQSTCFLVQENQTVLKHEGKDCNKRFAPESTFKIALSL MGFDSGILKDTLNPEWPYKKEYELYLNVWKYPHNPRTWIRDSCVWYSQVLTQQLG MTRFKNYVDAFHYGNQDISGDKGQNNGLTHSWLSSSLAISPSEQIQFLQKIVNKKLS VNPKAFTMTKDILYIQELAGGWKLYGKTGNGRQLTKDKSQKLSLQHGWFIGWIEKD GRVITFTKHIADSKKHVTFASFRAKNETLNQLFYLINELEK SEQ ID No. 495 MNIKTLLLITSAIFISACSPYIVTANPNHSASKSDEKAEKIKNLFNEVHTTGVLVIQQGQ TQQSYGNDLARASTEYVPASTFKMLNALIGLEHHKATTTEVFKWDGQKRLFPEWEK DMTLGDAMKASAIPVYQDLARRIGLELMSKEVKRVGYGNADIGTQVDNFWLVGPLK ITPQQEAQFAYKLANKTLPFSPKVQDEVQSMLFIEEKNGNKIYAKSGWGWDVDPQV GWLTGWVVQPQGNIVAFSLNLEMKKGIPSSVRKEITYKSLEQLGIL SEQ ID No. 496 MKFRHALSSAFVLLGCIAASAHAKTICTAIADAGTGKLLVQDGDCGRRASPASTFKIA ISLMGYDAGFLRNEHDPVLPYRDSYIAWGGEAWKQPTDPTRWLKYSVVWYSQQV AHHLGAQRFAQYAKAFGYGNADVSGDPGQNNGLDRAWIGSSLQISPLEQLEFLGK MLNRKLPVSPTAVDMTERIVESTTLADGTWHGKTGVSYPLLADGTRDWARGSGW FVGWIVRGNQTLVFARLTQDERKQPVSAGIRTREAFLRDLPRLLAAR SEQ ID No. 497 MKFRHALSSAFVLLGCIAASAHAKTICTAIADAGTGKLLVQDGDCGRRASPASTFKIA ISLMGYDAGFLRNEHDPVLPYRDSYIAWGGEAWKQPTDPTRWLKYPVVWYSQQV AHHLGAQRFAQYAKAFGYGNADVSGDPGQNNGLDRAWIGSSLQISPLEQLEFLGK MLNRKLPVSPTAVDMTERIVESTTLADGTVVHGKTGVSYPLLADGTRDWARGSGW FVGWIVRGKQTLVFARLTQDERKQPVSAGIRTREAFLRDLPRLLAAR SEQ ID No. 498 MRGKHTVILGAALSALFAGAAGAQMLECTLVADAASGQELYRKGACDKAFAPMSTF KVPLAVMGYDAGILVDAHNPRWDYKPEFNGYKFQQKTTDPTIWEKDSIVWYSQQLT RKMGQKRFAAYVAGFGYGNGDISGEPGKSNGLTHSWLGSSLKISPEGQVRFVRDL LSAKLPASKDAQQMTVSILPHFAAGDWAVQGKTGTGSFIDARGAKAPLGWFIGWAT HEERRVVFARMTAGGKKGEQPAGPAARDAFLKALPDLAKRF SEQ ID No. 499 MKFRHALSSAFVLLGCIAASAHAKTICTAIADAGTGKLLVQDGDCGRRASPASTFKIA ISLMGYDAGFLRNEHDPVLPYRDSYIAWGGEAWKQPTDPTRWLKYSVVWYSQQV AHHLGAQRFAQYAKAFGYGNADVSGDPGQNNGLDRAWIGSSLQISPLEQLEFLGK MLDRKLPVSPTAVDMTERIVESTTLADGTVVHGKTGVSYPLLADGTRDWARGSGW FVGWIVRGKQTLVFARLTQDERKQPVSAGIRTREAFLRDLPRLLAAR SEQ ID No. 500 MKFRHALSSAFVLLGCIAASAHAKTICTAIADAGTGKLLVQDGDCGRRASPASTFKIA ISLMGYDAGFLRNEHDPVLPYRDSYIAWGGEAWKQPTDPTRWLKYSVVWYSQQV AHHLGAQRFAQYAKAFGYGNADVSGDPGQNNGLDRAWIGSSLQISPLEQLEFLGK MLNRKLPVSPTAVDMTERIVESTTILADGTVVHGKTGVSYPLLADGTRDWARGSGW FVGWIVRGKQTLVFARLTQDERKQPVSAGIRTREAFLRDLPRLLAAR SEQ ID No. 501 MKTFAAYVIIACLSSTALAGSITENTSWNKEFSAEAVNGVFVLCKSSSKSCATNDLAR ASKEYLPVSTFKIPSAIIGLETGVIKNEHQVFKWDGKPRAMKQWERDLTLRGAIQVS AVPVFQQIAREVGEVRMQKYLKKFSYGNQNISGGIDKFWLEGQLRISAVNQVEFLE SLYLNKLSASKENQLIVKEALVTEAAPEYLVHSKTGFSGVGTESNPGVAWWVGWVE KETEVYFFAFNMDIDNESKLPLRKSIPTKIMESEGIIGG SEQ ID No. 502 MNIKALLLITSAIFISACSPYIVTANPNHSASKSDEKAEKIKNLFNEAHTTGVLVIQQGQ TQQSYGNDLARASTEYVPASTFKMLNALIGLEHHKATTTEVFKWDGKKRLFPEWEK DMTLGDAMKASAIPVYQDLARRIGLELMSKEVKRVGYGNADIGTQVDNFWLVGPLK ITPQQEAQFAYKLANKTLPFSQKVQDEVQSMLFIEEKNGNKIYAKSGWGWDVDPQV GWLTGWVVQPQGNIVAFSLNLEMKKGIPSSVRKEITYKSLEQLGIL SEQ ID No. 503 MNIKALLLITSAIFISACSPYIVSANPNHSASKSDEKAEKIKNLFNEAHTTGVLVIQQGQ TQQSYGNDLARASTEYVPASTFKMLNALIGLEHHKATTTEVFKWDGQKRLFPEWEK NMTLGDAMKASAIPVYQDLARRIGLELMSNEVKRVGYGNADIGTQVDNFWLVGPLK ITPQQEAQFAYKLANKTLPFSQKVQDEVQSMLFIEEKNGNKIYAKSGWGWDVNPQV GWLTGWVVQPQGNIVAFSLNLEMKKGIPSSVRKEITYKSLEQLGIL SEQ ID No. 504 MKTFAAYVITACLSSTALASSITENTFWNKEFSAEAVNGVFVLCKSSSKSCATNNLA RASKEYLPASTFKIPNAIIGLETGVIKNEHQVFKWDGKPRAMKQWERDLSLRGAIQV SAVPVFQQIAREVGEVRMQKYLKKFSYGNQNISGGIDKFWLEGQLRISAVNQVEFL ESLFLNKLSASKENQLIVKEALVTEAAPEYLVHSKTGFSGVGTESNPGVAWWVGWV EKGTEVYFFAFNMDIDNENKLPLRKSIPTKIMASEGIIGG SEQ ID No. 505 MKTIAAYLVLVFFAGTALSESISENLAWNKEFSSESVHGVFVLCKSSSNSCTTNNAT RASTAYIPASTFKIPNALIGLETGAIKDARQVFKWDGKPRAMKQWEKDLTLRGAIQV SAVPVFQQIARDIGKKRMQKYLNLFSYGNANIGGGIDKFWLEGQLRISAVNQVKFLE SLYLNNLPASKANQLIVKEAIVTEATPEYIVHSKTGYSGVGTESNPGVAWWVGWVE KGTEVYFFAFNMDIDNESKLPSRKSIPTKIMASEGIIIGG SEQ ID No. 506 MKKFILPIFSISILVSLSACSSIKTKSEDNFHISSQQHEKAIKSYFDEAQTQGVIIIKEGK NLSTYGNALARANKEYVPASTFKMLIALIGLENHKATTNEIFKWDGKKRTYPMWEKD MTLGEAMALSAVPVYQELARRTGLELMQKEVKRVNFGNTNIGTQVDNFWLVGPLKI TPVQEVNFADDLAHNRLPFKLETQEEVKKMLLIKEVNGSKIYAKSGWGMGVTPQVG WLTGWVEQANGKKIPFSLNLEMKEGMSGSIRNEITYKSLENLGII SEQ ID No. 507 MNIKALLLITSAIFISACSPYIVTANPNHSASKSDDKAEKIKNLFNEAHTTGVLVIHQGQ TQQSYGNDLARASTEYVPASTFKMLNALIGLEHHKATTTEVFKWNGQKRLFPEWEK DMTLGDAMKASAIPVYQDLARRIGLELMSNEVKRVGYGNADIGTQVDNFWLVGPLK ITPQQEAQFAYKLANKTLPFSQKVQDEVQSMLFIEEKNGNKIYAKSGWGWDVDPQV GWLTGWVVQPQGNIVAFSLNLEMKKGIPSSVRKEITYKSLEQLGIL SEQ ID No. 508 MNIKALLLITSAISISACSPYIVTANPNHSASKSDEKAEKIKNLFNEAHTTGVLVIQQGQ TQQSYGNDLARASTEYVPASTFKMLNALIGLEHHKATTTEVFKWDGQKRLFPEWEK DMTLGDAIKASAIPVYQDLARRIGLELMSKEVKRVGYGNADIGTQVDNFWLVGPLKI TPQQEAQFAYKLANKTLPFSQKVQDEVQSMLFIEEKNGNKIYAKSGWGWDVDPQV GWLTGWVVQPQGNIVAFSLNLEMKKGIPSSVRKEITYKSLEQLGIL

said peptides being chosen, preferably, from the peptides of sequence SEQ ID No. 509 to SEQ ID No. 523, SEQ ID No. 525 to SEQ ID No. 572, SEQ ID No. 574 to SEQ ID No. 604, SEQ ID No. 606 to SEQ ID No. 618, SEQ ID No. 620 to SEQ ID No. 696, SEQ ID No. 698 to SEQ ID No. 1077 and SEQ ID No. 1098 to SEQ ID No. 1109, as defined hereafter:

Peptide Position of the peptide in the OXA Clinical SEQ ID No. Amino acid sequence protein(s) interest SEQ ID AAAYELAENLFEAGQADGWR 183-202 for the protein of SEQ No. 433 2d No. 509 SEQ ID AAEGFIPASTFK 86-97 for the protein of SEQ No. 381 2df No. 510 SEQ ID AALGR 41-45 for the protein of SEQ No. 382 2df No. 511 SEQ ID ADGQVVAFALNMQMK 241-255 for the proteins of SEQ No. 410, 2df No. 512 413, 458 SEQ ID ADINEIFK 95-102 for the protein of SEQ No. 366 2df No. 513 SEQ ID ADWGK 50-54 for the protein of SEQ No. 382 2df No. 514 SEQ ID AEGAIVISDER 40-50 for the proteins of SEQ No. 369, 372 OXA No. 515 SEQ ID AFALNLDIDK 222-231 for the protein of SEQ No. 385 2d No. 516 SEQ ID AFAPMSTFK 49-57 for the protein of SEQ No. 498; 60-68 OXA No. 517 for the protein of sequence SEQ ID No. 351 SEQ ID AFGYGNADVSGDPGQNNGLDR 127-147 for the proteins of SEQ No. 496, 2d No. 518 497, 499, 500 SEQ ID AFTMTK 174-179 for the protein of SEQ No. 494 2d No. 519 SEQ ID AGDDIALR 256-263 for the proteins of SEQ No. 410, 2df No. 520 413, 458 SEQ ID AGHVYAFALNIDMPR 233-247 for the protein of SEQ No. 379 2df No. 521 SEQ ID AGLWR 11-15 for the protein of SEQ No. 382 2df No. 522 SEQ ID AHTEYVPASTFK 73-84 for the proteins of SEQ No. 447, 466 2df No. 523 SEQ ID AIIPWDGK 112-119 for the protein of SEQ No. 382 2df No. 524 SEQ ID AIIPWDGKPR 112-121 for the protein of SEQ No. 382 2df No. 525 SEQ ID AISDITITR 190-198 for the protein of SEQ No. 386 2d No. 526 SEQ ID AISGK 82-86 for the protein of SEQ No. 470 2df No. 527 SEQ ID ALGQDR 121-126 for the protein of SEQ No. 433 2d No. 528 SEQ ID ALPDLAK 256-262 for the protein of SEQ No. 498 2d No. 529 SEQ ID ALQAK 254-258 for the protein of SEQ No. 470 2df No. 530 SEQ ID AMETFSPASTFK 50-61 for the protein of SEQ No. 385 2d No. 531 SEQ ID AMLFLQER 196-203 for the protein of SEQ No. 469 2df No. 532 SEQ ID AMLVFDPVR 55-63 for the proteins of SEQ No. 350, 367, OXA No. 533 370, 415, 443, 481, 488; 44-52 for the protein of sequence SEQ ID No. 362 SEQ ID AMTLLESGPGWELHGK 189-204 for the protein of SEQ No. 380 2d No. 534 SEQ ID ANLHITLHGK 199-208 for the protein of SEQ No. 386 2d No. 535 SEQ ID ANQLIVK 183-189 for the proteins of SEQ No. 489, 505 OXA No. 536 SEQ ID ANTEYVPASTFK 71-82 for the proteins of SEQ No. 366, 374, 2df No. 537 387, 440, 441, 459, 460, 461, 462, 463, 464, 465, 486, 493; 66-77 for the protein of sequence SEQ ID No. 469 SEQ ID ANVSR 133-137 for the protein of SEQ No. 380 2d No. 538 SEQ ID APIGWFIGWATR 224-235 for the protein of SEQ No. 351 2de No. 539 SEQ ID APLGWFIGWATHEER 213-227 for the protein of SEQ No. 498 2d No. 540 SEQ ID AQDEVQSMLFIEEK 196-209 for the protein of SEQ No. 403 2df No. 541 SEQ ID AQGVIVLWNENK 40-51 for the protein of SEQ No. 384 2df No. 542 SEQ ID ASAIAVYQDLAR 126-137 for the protein of SEQ No. 467 2df No. 543 SEQ ID ASAILVYQDLAR 126-137 for the proteins of SEQ No. 417, 2df No. 544 426, 457, 472 SEQ ID ASAIPVYQDLAR 126-137 for the proteins of SEQ No. 388, 2df No. 545 389, 390, 391, 392, 393, 394, 395, 396, 398, 399, 402, 403, 404, 405, 406, 407, 408, 409, 411, 412, 416, 418, 419, 420, 423, 424, 425, 427, 428, 434, 436, 437, 439, 444, 445, 446, 448, 453, 454, 455, 456, 468, 475, 478, 479, 480, 482, 483, 495, 502, 503, 507, 508; 120-131 for the proteins of sequence SEQ ID No. 431, 432 SEQ ID ASAIPVYQDLPR 126-137 for the protein of SEQ No. 397 2df No. 546 SEQ ID ASAIQVYQDLAR 126-137 for the proteins of SEQ No. 421, 473 2df No. 547 SEQ ID ASAISVYQDLAR 126-137 for the proteins of SEQ No. 400, 487 2df No. 548 SEQ ID ASALPVYQDLAR 126-137 for the proteins of SEQ No. 401, 422 2df No. 549 SEQ ID ASAMPVYQDLAR 126-137 for the protein of SEQ No. 474 2df No. 550 SEQ ID ASAVPVYQDLAR 126-137 for the proteins of SEQ No. 438, 2df No. 551 451, 452 SEQ ID ASIEYVPASTFK 72-83 for the proteins of SEQ No. 399, 403 2df No. 552 SEQ ID ASNVPVYQELAR 113-124 for the protein of SEQ No. 380 2d No. 553 SEQ ID ASPASTFK 49-56 for the proteins of SEQ No. 496, 497, 2d No. 554 499, 500 SEQ ID ASTAYIPASTFK 59-70 for the proteins of SEQ No. 489, 505 OXA No. 555 SEQ ID ASTEYVPASTFK 72-83 for the proteins of SEQ No. 388, 389, 2df No. 556 390, 391, 392, 393, 394, 395, 396, 397, 398, 400, 401, 402, 404, 405, 406, 407, 408, 409, 411, 412, 416, 417, 418, 419, 420, 421, 422, 423, 424, 425, 426, 427, 428, 434, 436, 437, 438, 439, 444, 445, 446, 448, 451, 452, 453, 454, 455, 456, 457, 467, 468, 472, 473, 474, 475, 478, 479, 480, 482, 483, 487, 495, 502, 503, 507, 508; 66-77 for the proteins of sequence SEQ ID No. 431, 432 SEQ ID ASTTEVFK 96-103 for the protein of SEQ No. 444 2df No. 557 SEQ ID ATSTEIFK 99-106 for the proteins of SEQ No. 410, 413, 2df No. 558 458 SEQ ID ATTNEIFK 97-104 for the proteins of SEQ No. 364, 365, 2df No. 559 371, 414, 449, 466, 506; 90-97 for the protein of sequence SEQ ID No. 469 SEQ ID ATTTAVFK 96-103 for the protein of SEQ No. 396 2df No. 560 SEQ ID ATTTEIFK 97-104 for the protein of SEQ No. 447; 96-103 No. 561 for the proteins of sequence SEQ ID No. 2df 399, 403, 411 SEQ ID ATTTEVFK 96-103 for the proteins of SEQ No. 388, 389, 2df No. 562 390, 391, 392, 393, 394, 397, 398, 400, 401, 402, 404, 405, 406, 407, 408, 409, 412, 416, 417, 418, 419, 420, 421, 422, 423, 424, 425, 426, 427, 434, 436, 437, 438, 439, 445, 446, 448, 451, 452, 453, 454, 455, 456, 457, 467, 468, 472, 473, 474, 475, 478, 479, 480, 482, 483, 487, 495, 502, 503, 507, 508; 90-97 for the proteins of sequence SEQ ID No. 431, 432 SEQ ID AVSDITILEQTDNYTLHGK 191-209 for the protein of SEQ No. 477 OXA No. 563 SEQ ID AVSDITILEQTYNYTLHGK 191-209 for the proteins of SEQ No. 429, 430 2d No. 564 SEQ ID AVVPHFEAGDWDVQGK 195-210 for the protein of SEQ No. 351 2de No. 565 SEQ ID AWEHDMSLR 100-108 for the protein of SEQ No. 380 2d No. 566 SEQ ID AWIGSSLQISPLEQLEFLGK 148-167 for the proteins of SEQ No. 496, 2d No. 567 497, 499, 500 SEQ ID CAAQMAPDSTFK 63-74 for the protein of SEQ No. 376 2d No. 568 SEQ ID CATQMAPDSTFK 48-59 for the protein of SEQ No. 361; 63-74 2d No. 569 for the protein of sequence SEQ ID No. 360 SEQ ID CTIIADAITGNTLYETGECAR 32-52 for the protein of SEQ No. 349 2d No. 570 SEQ ID DAFLK 251-255 for the protein of SEQ No. 498 2d No. 571 SEQ ID DDFILHGK 189-196 for the protein of SEQ No. 377 2d No. 572 SEQ ID DDQEVLPYGGK 92-102 for the protein of SEQ No. 379 2df No. 573 SEQ ID DDVLK 87-91 for the protein of SEQ No. 470 2df No. 574 SEQ ID DEFHVFR 90-96 for the proteins of SEQ No. 355, 363 2d No. 575 SEQ ID DEFQIFR 90-96 for the proteins of SEQ No. 350, 367, OXA No. 576 370, 375, 415, 443, 481, 488; 79-85 for the protein of sequence SEQ ID No. 362 SEQ ID DEFQVFR 90-96 for the proteins of SEQ No. 356, 369, 2d No. 577 372, 373, 484, 491 SEQ ID DELVR 260-264 for the protein of SEQ No. 433 2d No. 578 SEQ ID DETSR 112-116 for the protein of SEQ No. 381 2df No. 579 SEQ ID DFDYGNQDFSGDK 141-153 for the proteins of SEQ No. 360, 2d No. 580 376; 126-138 for the protein of sequence SEQ ID No. 361 SEQ ID DFTLGEAMQASTVPVYQELAR 120-140 for the proteins of SEQ No. 410, 2df No. 581 413, 458 SEQ ID DGNITSVAINIDMLSEADAPK 250-270 for the protein of SEQ No. 382 2df No. 582 SEQ ID DHDLITAMK 108-116 for the proteins of SEQ No. 384, 485 2df No. 583 SEQ ID DIAAWNR 101-107 for the proteins of SEQ No. 384, 485 2df No. 584 SEQ ID DIGEDK 131-136 for the protein of SEQ No. 373 2d No. 585 SEQ ID DILYIQELAGGWK 180-192 for the protein of SEQ No. 494 2de No. 586 SEQ ID DITILEK 181-187 for the protein of SEQ No. 377 2d No. 587 SEQ ID DLLSAK 166-171 for the protein of SEQ No. 498 2d No. 588 SEQ ID DLMITEAGR 195-203 for the proteins of SEQ No. 369, 2d No. 589 372, 373 SEQ ID DLMIVEAGR 195-203 for the proteins of SEQ No. 350, OXA No. 590 356, 367, 370, 375, 415, 443, 481, 488, 491; 184-192 for the protein of sequence SEQ ID No. 362 SEQ ID DLMIVEAK 195-202 for the proteins of SEQ No. 355, 363 2d No. 591 SEQ ID DLPLR 243-247 for the protein of SEQ No. 470 2df No. 592 SEQ ID DLSGNPGK 131-138 for the protein of SEQ No. 347 2d No. 593 SEQ ID DLSLR 105-109 for the proteins of SEQ No. 357, OXA No. 594 358, 359, 368, 383, 442, 471, 504; 106-110 for the protein of sequence SEQ ID No. 490 SEQ ID DLTLR 105-109 for the proteins of SEQ No. 352, OXA No. 595 435, 492, 501, 505; 96-100 for the proteins of sequence SEQ ID No. 348, 353, 354 SEQ ID DMTLGDAIK 117-125 for the proteins of SEQ No. 468, 508 2df No. 596 SEQ ID DMTLGDAMALSAVPVYQELAR 118-138 for the protein of SEQ No. 447 2df No. 597 SEQ ID DMTLGDAMK 117-125 for the proteins of SEQ No. 389, 2df No. 598 390, 391, 394, 395, 398, 399, 400, 401, 403, 404, 407, 408, 409, 411, 412, 417, 418, 420, 421, 423, 425, 426, 427, 428, 436, 437, 438, 439, 444, 451, 452, 453, 454, 455, 456, 457, 467, 472, 473, 474, 478, 479, 480, 482, 483, 487, 495, 502, 507 SEQ ID DMTLGEAMALSAVPVYQDLAR 118-138 for the protein of SEQ No. 466 2df No. 599 SEQ ID DMTLGEAMALSAVPVYQELAR 118-138 for the proteins of SEQ No. 364, 2df No. 600 365, 371, 414, 449, 506 SEQ ID DMTLGEAMK 116-124 for the proteins of SEQ No. 366, 2df No. 601 374, 387, 440, 441, 459, 460, 461, 462, 463, 464, 465, 486, 493 SEQ ID DMTLGQAMQASAVPVYQELAR 111-131 for the protein of SEQ No. 469 2df No. 602 SEQ ID DNNGK 214-218 for the protein of SEQ No. 349 2d No. 603 SEQ ID DQDLR 110-114 for the proteins of SEQ No. 350, 2d No. 604 356, 367, 369, 370, 372, 373, 375, 415, 443, 481, 484, 488, 491; 99-103 for the protein of sequence SEQ ID No. 362 SEQ ID DQQIGWFVGWASK 213-225 for the protein of SEQ No. 347 2d No. 605 SEQ ID DQQIGWFVGWASKPGK 213-228 for the protein of SEQ No. 347 2d No. 606 SEQ ID DQQVQVYGNDLNR 53-65 for the protein of SEQ No. 469 2df No. 607 SEQ ID DQSFR 132-136 for the protein of SEQ No. 381 2df No. 608 SEQ ID DQTLESAFK 105-113 for the protein of SEQ No. 470 2df No. 609 SEQ ID DSCVWYSQVLTQQLGMTR 98-115 for the protein of SEQ No. 494 2de No. 610 SEQ ID DSIVWYSQELTR 113-124 for the protein of SEQ No. 351 2de No. 611 SEQ ID DSIVWYSQQLTR 102-113 for the protein of SEQ No. 498 2d No. 612 SEQ ID DSNLR 109-113 for the proteins of SEQ No. 429, 2d No. 613 430, 477; 96-100 for the proteins of sequence SEQ ID No. 377, 386 SEQ ID DSYIAWGGEAWK 81-92 for the proteins of SEQ No. 496, 497, 2d No. 614 499, 500 SEQ ID DTLNPEWPYK 67-76 for the protein of SEQ No. 494 2de No. 615 SEQ ID DVDEVFYK 88-95 for the proteins of SEQ No. 386, 429, 2d No. 616 430, 477 SEQ ID DVSGDPGK 144-151 for the protein of SEQ No. 351 2de No. 617 SEQ ID DWILR 204-208 for the proteins of SEQ No. 355, 363 2d No. 618 SEQ ID DWPAMAGAWR 265-274 for the protein of SEQ No. 433 2d No. 619 SEQ ID EAFLR 256-260 for the proteins of SEQ No. 496, 2d No. 620 497, 499, 500 SEQ ID EAIAR 250-254 for the proteins of SEQ No. 355, 2d No. 621 363, 369, 372, 373, 375, 484 SEQ ID EAIVR 250-254 for the proteins of SEQ No. 350, OXA No. 622 356, 367, 370, 415, 443, 481, 488, 491; 239-243 for the protein of sequence SEQ ID No. 362 SEQ ID EAIVTEATPEYIVHSK 190-205 for the proteins of SEQ No. 489, 505 OXA No. 623 SEQ ID EALVTEAAPEYLVHSK 190-205 for the proteins of SEQ No. 352, OXA No. 624 357, 358, 359, 368, 383, 435, 442, 471, 492, 501, 504; 181-196 for the proteins of sequence SEQ ID No. 348, 353, 354 SEQ ID EALVTEAPEYLVHSK 191-205 for the protein of SEQ No. 490 2d No. 625 SEQ ID EEIVR 240-244 for the protein of SEQ No. 377 2d No. 626 SEQ ID EEVLAALPAQLK 251-262 for the protein of SEQ No. 347 2d No. 627 SEQ ID EFNGSK 209-214 for the protein of SEQ No. 447 2df No. 628 SEQ ID EFSAEAVNGVFVLCK 31-45 for the proteins of SEQ No. 352, 357, OXA No. 629 358, 359, 368, 383, 435, 442, 471, 490, 492, 501, 504; 22-36 for the proteins of sequence SEQ ID No. 348, 353, 354 SEQ ID EFSSESVHGVFVLCK 31-45 for the proteins of SEQ No. 489, 505 OXA No. 630 SEQ ID EGDMAK 248-253 for the protein of SEQ No. 379 2df No. 631 SEQ ID EGMSGSIR 254-261 for the proteins of SEQ No. 364, 2df No. 632 371, 414, 449, 506 SEQ ID EGMTGSIR 254-261 for the protein of SEQ No. 365 2df No. 633 SEQ ID EGSCDK 54-59 for the protein of SEQ No. 351 2de No. 634 SEQ ID EIAVWNR 125-131 for the protein of SEQ No. 381 2df No. 635 SEQ ID EIAYK 262-266 for the protein of SEQ No. 480 2df No. 636 SEQ ID EIFER 20-24 for the protein of SEQ No. 377 2d No. 637 SEQ ID EIFYHYR 79-85 for the protein of SEQ No. 385 2d No. 638 SEQ ID EIGDDK 131-136 for the proteins of SEQ No. 350, OXA No. 639 367, 370, 415, 443, 481, 488; 120-125 for the protein of sequence SEQ ID No. 362 SEQ ID EIGDGK 131-136 for the protein of SEQ No. 375 2d No. 640 SEQ ID EIGEDK 131-136 for the proteins of SEQ No. 356, 2d No. 641 372, 491 SEQ ID EIGEDNAR 131-138 for the protein of SEQ No. 484 OXA No. 642 SEQ ID EIGENK 131-136 for the proteins of SEQ No. 355, 363 2d No. 643 SEQ ID EIGPK 153-157 for the protein of SEQ No. 381 2df No. 644 SEQ ID EIGSEIDK 136-143 for the protein of SEQ No. 377 2d No. 645 SEQ ID EITYK 262-266 for the proteins of SEQ No. 389, 2df No. 646 390, 391, 392, 393, 394, 395, 396, 397, 398, 399, 400, 401, 402, 403, 404, 405, 406, 407, 408, 409, 411, 412, 416, 417, 418, 419, 420, 421, 422, 423, 424, 425, 426, 427, 428, 434, 436, 437, 438, 444, 445, 446, 448, 451, 452, 453, 454, 455, 456, 457, 467, 468, 472, 473, 474, 475, 478, 479, 482, 483, 487, 495, 502, 503, 507, 508; 263-267 for the proteins of sequence SEQ ID No. 364, 365, 371, 414, 447, 449, 466, 506; 256-260 for the proteins of sequence SEQ ID No. 431, 432 SEQ ID EITYR 262-266 for the protein of SEQ No. 388 2df No. 647 SEQ ID EMIYLK 181-186 for the protein of SEQ No. 385 2d No. 648 SEQ ID EMLYVER 205-211 for the proteins of SEQ No. 410, 2df No. 649 413, 458 SEQ ID EMTYK 262-266 for the protein of SEQ No. 439 2df No. 650 SEQ ID ENIEK 138-142 for the proteins of SEQ No. 429, 2d No. 651 430, 477; 137-141 for the protein of sequence SEQ ID No. 386 SEQ ID ENQLIVK 183-189 for the proteins of SEQ No. 352, OXA No. 652 357, 358, 359, 368, 383, 435, 442, 471, 492, 501, 504; 174-180 for the proteins of sequence SEQ ID No. 348, 353, 354; 184-190 for the protein of sequence SEQ ID No. 490 SEQ ID EQAILLFR 156-163 for the protein of SEQ No. 385 2d No. 653 SEQ ID EQIQFLLR 165-172 for the protein of SEQ No. 349 2d No. 654 SEQ ID EQLAFDPQVQQQVK 182-195 for the protein of SEQ No. 469 2df No. 655 SEQ ID EQVDFVQR 189-196 for the protein of SEQ No. 382 2df No. 656 SEQ ID ETEVYFFAFNMDIDNESK 229-246 for the proteins of SEQ No. 352, OXA No. 657 435, 492, 501; 220-237 for the proteins of sequence SEQ ID No. 348, 353, 354 SEQ ID ETTTPR 90-95 for the protein of SEQ No. 347 2d No. 658 SEQ ID EVGEIR 126-131 for the protein of SEQ No. 489 2d No. 659 SEQ ID EVGEVR 126-131 for the proteins of SEQ No. 352, OXA No. 660 357, 358, 359, 368, 383, 435, 442, 471, 492, 501, 504; 117-122 for the proteins of sequence SEQ ID No. 348, 353, 354; 127-132 for the protein of sequence SEQ ID No. 490 SEQ ID EVNGSK 209-214 for the proteins of SEQ No. 364, 2df No. 661 365, 371, 414, 449, 466, 506 SEQ ID EWQENK 24-29 for the proteins of SEQ No. 378, 450, 2df No. 662 476, 485 SEQ ID EYELYLNVWK 78-87 for the protein of SEQ No. 494 2de No. 663 SEQ ID EYLPASTFK 62-70 for the proteins of SEQ No. 352, 357, OXA No. 664 358, 359, 368, 383, 435, 442, 471, 492, 504; 53-61 for the proteins of sequence SEQ ID No. 348, 353, 354; 63-71 for the protein of sequence SEQ ID No. 490 SEQ ID EYLPVSTFK 62-70 for the protein of SEQ No. 501 2de No. 665 SEQ ID EYNTSGTFVFYDGK 27-40 for the protein of SEQ No. 385 2d No. 666 SEQ ID EYVPASTFX 75-83 for the proteins of SEQ No. 388, 389, 2df No. 667 390, 391, 392, 393, 394, 395, 396, 397, 398, 399, 400, 401, 402, 403, 404, 405, 406, 407, 408, 409, 411, 412, 416, 417, 418, 419, 420, 421, 422, 423, 424, 425, 426, 427, 428, 434, 436, 437, 438, 439, 444, 445, 446, 448, 451, 452, 453, 454, 455, 456, 457, 467, 468, 472, 473, 474, 475, 478, 479, 480, 482, 483, 487, 495, 502, 503, 507, 508; 69-77 for the proteins of sequence SEQ ID No. 431, 432, 469; 74-82 for the proteins of sequence SEQ ID No. 366, 374, 387, 440, 441, 459, 460, 461, 462, 463, 464, 465, 486, 493; 76-84 for the proteins of sequence SEQ ID No. 364, 365, 371, 414, 447, 449, 466, 506 SEQ ID FAAYVAGFGYGNGDISGEPGK 120-140 for the protein of SEQ No. 498 2d No. 668 SEQ ID FAPESTFK 45-52 for the protein of SEQ No. 494 2de No. 669 SEQ ID FAQYAK 121-126 for the proteins of SEQ No. 496, 2d No. 670 497, 499, 500 SEQ ID FDYGNK 138-143 for the protein of SEQ No. 351 2de No. 671 SEQ ID FDYGNR 146-151 for the protein of SEQ No. 379; 125-130 No. 672 for the protein of sequence SEQ ID No. 2d 347 SEQ ID FEDLYK 232-237 for the protein of SEQ No. 385 2d No. 673 SEQ ID FEDTFHISNQK 27-37 for the protein of SEQ No. 466 2df No. 674 SEQ ID FEDTFHTSNQQHEK 27-40 for the protein of SEQ No. 447 2df No. 675 SEQ ID FEYGNQDVSGDSGK 133-146 for the protein of SEQ No. 349 2d No. 676 SEQ ID FFSDFQAK 34-41 for the protein of SEQ No. 375 2d No. 677 SEQ ID FFSDLQAEGAIVIADER 34-50 for the proteins of SEQ No. 373, 484 2d No. 678 SEQ ID FFSDLR 34-39 for the proteins of SEQ No. 369, 372 OXA No. 679 SEQ ID FFSEFQAK 34-41 for the proteins of SEQ No. 350, 356, OXA No. 680 367, 370, 415, 443, 481, 488, 491; 23-30 for the protein of sequence SEQ ID No. 362 SEQ ID FGLEGQLR 153-160 for the protein of SEQ No. 359 2de No. 681 SEQ ID FILPIFSISILVSLSACSSIK 4-24 for the proteins of SEQ No. 364, 365, 2df No. 682 371, 414, 449, 506 SEQ ID FLALLFSAVVVSLGHAQDK 5-24 for the protein of SEQ No. 363 2d No. 683 SEQ ID FLALLFSAVVLVSLGHAQEK 5-24 for the protein of SEQ No. 355 2d No. 684 SEQ ID FLESLYLNNLPASK 169-182 for the proteins of SEQ No. 489, 505 OXA No. 685 SEQ ID FLLEGQLR 153-160 for the protein of SEQ No. 442 2de No. 686 SEQ ID FQQYVDR 118-124 for the protein of SEQ No. 347 2d No. 687 SEQ ID FSDYVQR 131-137 for the protein of SEQ No. 351 2de No. 688 SEQ ID FSTASTFK 63-70 for the protein of SEQ No. 470 2df No. 689 SEQ ID FSWDGK 117-122 for the protein of SEQ No. 381 2df No. 690 SEQ ID FSYGNQNISGGIDK 139-152 for the proteins of SEQ No. 352, OXA No. 691 357, 358, 359, 368, 383, 435, 442, 501, 504; 130-143 for the proteins of sequence SEQ ID No. 348, 353, 354; 140-153 for the protein of sequence SEQ ID No. 490 SEQ ID FSYGNQNISGGTDK 139-152 for the protein of SEQ No. 471 2de No. 692 SEQ ID FSYGSQNISGGIDK 139-152 for the protein of SEQ No. 492 2de No. 693 SEQ ID FTEYVK 126-131 for the protein of SEQ No. 349 2d No. 694 SEQ ID FVAHK 173-177 for the protein of SEQ No. 349 2d No. 695 SEQ ID FVPASTYK 62-69 for the protein of SEQ No. 380 2d No. 696 SEQ ID FVYDLAQGQLPFK 184-196 for the proteins of SEQ No. 410, 2df No. 697 413, 458 SEQ ID FVYDLAQGQLPFKPEVQQQVK 184-204 for the proteins of SEQ No. 410, 2df No. 698 413, 458 SEQ ID FWLEDQLR 153-160 for the proteins of SEQ No. 358, 2de No. 699 435, 471, 492; 144-151 for the proteins of sequence SEQ ID No. 348, 353 SEQ ID FWLEGPLK 144-151 for the protein of SEQ No. 377 2d No. 700 SEQ ID FWLEGQLR 153-160 for the proteins of SEQ No. 352, OXA No. 701 357, 368, 383, 489, 501, 504, 505; 144-151 for the protein of sequence SEQ ID No. 354; 154-161 for the protein of sequence SEQ ID No. 490 SEQ ID FYPASSFK 53-60 for the protein of SEQ No. 377 2d No. 702 SEQ ID FYPASTFK 66-73 for the proteins of SEQ No. 386, 429, 2d No. 703 430, 477 SEQ ID GACDK 44-48 for the protein of SEQ No. 498 2d No. 704 SEQ ID GAEVYFFAFNMDIDNENK 229-246 for the proteins of SEQ No. 383, 490 2d No. 705 SEQ ID GAIQVSAVPVFQQIAR 110-125 for the proteins of SEQ No. 352, OXA No. 706 357, 358, 359, 368, 383, 435, 442, 471, 489, 492, 501, 504, 505; 101-116 for the proteins of sequence SEQ ID No. 348, 354; 111-126 for the protein of sequence SEQ ID No. 490 SEQ ID GAIQVSAVPVFQQITR 101-116 for the protein of SEQ No. 353 2de No. 707 SEQ ID GDYWIDGNLEISAREQISFER 156-176 for the proteins of SEQ No. 369, 372 OXA No. 708 SEQ ID GDYWIDGNLK 156-165 for the protein of SEQ No. 373 2d No. 709 SEQ ID GELPVSEDALEMTK 181-194 for the protein of SEQ No. 351 2de No. 710 SEQ ID GEQPAGPAAR 241-250 for the protein of SEQ No. 498; 252-261 OXA No. 711 for the protein of sequence SEQ ID No. 351 SEQ ID GFAGHNQDQDLR 103-114 for the proteins of SEQ No. 350, OXA No. 712 367, 370, 415, 443, 481, 488; 92-103 for the protein of sequence SEQ ID No. 362 SEQ ID GIPSSVR 254-260 for the proteins of SEQ No. 389, 2df No. 713 390, 391, 392, 393, 394, 395, 397, 398, 399, 400, 401, 402, 403, 404, 405, 406, 407, 408, 409, 411, 412, 416, 417, 418, 419, 420, 421, 422, 423, 424, 425, 426, 427, 428, 434, 436, 437, 438, 439, 444, 445, 446, 448, 451, 452, 453, 454, 455, 456, 457, 467, 468, 472, 473, 474, 475, 478, 479, 480, 482, 483, 487, 495, 502, 503, 507, 508; 248-254 for the proteins of sequence SEQ ID No. 431, 432 SEQ ID GISSSVR 254-260 for the protein of SEQ No. 388 2df No. 714 SEQ ID GLNGTFVVYDLK 26-37 for the protein of SEQ No. 377 2d No. 715 SEQ ID GMEIWNSNHTPK 101-112 for the proteins of SEQ No. 360, 2d No. 716 376; 86-97 for the protein of sequence SEQ ID No. 361 SEQ ID GNQTLVFAR 230-238 for the protein of SEQ No. 496 2d No. 717 SEQ ID GNYWIDGNLEISAHEQISFLR 156-176 for the protein of SEQ No. 484 OXA No. 718 SEQ ID GPLEISAFEEAR 164-175 for the protein of SEQ No. 379 2df No. 719 SEQ ID GPLTITPIQEVK 172-183 for the proteins of SEQ No. 410, 2df No. 720 413, 458 SEQ ID GSGWFVGWIVR 219-229 for the proteins of SEQ No. 496, 2d No. 721 497, 499, 500 SEQ ID GSLLEWDQK 66-74 for the protein of SEQ No. 381 2df No. 722 SEQ ID GTEVYFFAFNMDIDNENK 229-246 for the proteins of SEQ No. 357, OXA No. 723 358, 359, 368, 442, 471, 504 SEQ ID GTEVYFFAFNMDIDNESK 229-246 for the proteins of SEQ No. 489, 505 OXA No. 724 SEQ ID GTFVEYDVQR 38-47 for the protein of SEQ No. 380 2d No. 725 SEQ ID GTIVVADER 42-50 for the proteins of SEQ No. 350, 356, OXA No. 726 367, 370, 375, 415, 443, 481, 488, 491; 31-39 for the protein of sequence SEQ ID No. 362 SEQ ID GTIVVLDAR 63-71 for the protein of SEQ No. 382 2df No. 727 SEQ ID GTIVVVDER 42-50 for the proteins of SEQ No. 355, 363 2d No. 728 SEQ ID GTLPFSAR 200-207 for the protein of SEQ No. 382 2df No. 729 SEQ ID GTPSSVR 254-260 for the protein of SEQ No. 396 2df No. 730 SEQ ID HALSSAFVLLGCIAASAHAK 5-24 for the proteins of SEQ No. 496, 497, 2d No. 731 499, 500 SEQ ID HIADSK 234-239 for the protein of SEQ No. 494 2de No. 732 SEQ ID HNGLTHAWLASSLK 152-165 for the protein of SEQ No. 351 2de No. 733 SEQ ID HNGLTQSWLMSSLTISPK 147-164 for the protein of SEQ No. 349 2d No. 734 SEQ ID HNGTDGAWIISSLR 148-161 for the protein of SEQ No. 433 2d No. 735 SEQ ID HTLSVFDQER 54-63 for the protein of SEQ No. 373 2d No. 736 SEQ ID HVTFASFR 241-248 for the protein of SEQ No. 494 2de No. 737 SEQ ID IAISLMGYDAGFLR 57-70 for the proteins of SEQ No. 496, 497, 2d No. 738 499, 500 SEQ ID IALSLMAFDAEIIDQK 75-90 for the proteins of SEQ No. 360, 376; 2d No. 739 60-75 for the protein of sequence SEQ ID No. 361 SEQ ID IALSLMGFDSGILK 53-66 for the protein of SEQ No. 494 2de No. 740 SEQ ID IANALIGLENHK 87-98 for the proteins of SEQ No. 410, 413, 2df No. 741 458 SEQ ID IAWIVGEVYLK 205-215 for the protein of SEQ No. 385 2d No. 742 SEQ ID IDTFWLDNSLK 141-151 for the protein of SEQ No. 385 2d No. 743 SEQ ID IDYYNLDR 41-48 for the protein of SEQ No. 377 2d No. 744 SEQ ID IFNALIALDSGVIK 62-75 for the protein of SEQ No. 385 2d No. 745 SEQ ID IFNSLLALDSGALDNER 95-111 for the protein of SEQ No. 382 2df No. 746 SEQ ID IFNTLIGLENGIVK 61-74 for the protein of SEQ No. 377 2d No. 747 SEQ ID IGLDLMQK 138-145 for the proteins of SEQ No. 366, 2df No. 748 374, 387, 440, 441, 459, 460, 461, 462, 463, 464, 465, 486, 493 SEQ ID IGLEK 131-135 for the protein of SEQ No. 477 OXA No. 749 SEQ ID IGLELMQQEVQR 133-144 for the protein of SEQ No. 469 2df No. 750 SEQ ID IGLELMSK 139-146 for the proteins of SEQ No. 389, 2df No. 751 390, 391, 393, 395, 398, 399, 400, 401, 402, 403, 404, 408, 409, 411, 412, 417, 419, 420, 421, 422, 423, 424, 425, 426, 427, 428, 436, 437, 438, 439, 451, 452, 453, 454, 455, 456, 457, 467, 468, 472, 473, 474, 478, 479, 480, 482, 483, 487, 495, 502, 508 SEQ ID IGLELMSNEVK 139-149 for the proteins of SEQ No. 388, 2df No. 752 392, 394, 396, 397, 405, 406, 407, 416, 418, 434, 444, 445, 446, 448, 475, 503, 507; 133-143 for the proteins of sequence SEQ ID No. 431, 432 SEQ ID IGLER 126-130 for the protein of SEQ No. 380 2d No. 753 SEQ ID IGLNK 130-134 for the proteins of SEQ No. 360, 2d No. 754 376; 115-119 for the protein of sequence SEQ ID No. 361 SEQ ID IGLNLMQK 140-147 for the protein of SEQ No. 466 2df No. 755 SEQ ID IGPSLMQSELQR 142-153 for the proteins of SEQ No. 410, 2df No. 756 413, 458 SEQ ID IGYGNMQIGTEVDQFWLK 154-171 for the proteins of SEQ No. 413, 458 2df No. 757 SEQ ID IGYGNMQMGTEVDQFWLK 154-171 for the protein of SEQ No. 410 2df No. 758 SEQ ID IINHNLPVK 167-175 for the protein of SEQ No. 361; 182-190 2d No. 759 for the protein of sequence SEQ ID No. 360 SEQ ID IINHNLPVR 182-190 for the protein of SEQ No. 376 2d No. 760 SEQ ID ILFQQGTQQACAER 41-54 for the protein of SEQ No. 433 2d No. 761 SEQ ID ILNNWFK 20-26 for the protein of SEQ No. 385 2d No. 762 SEQ ID ILNTLISLEEK 71-81 for the protein of SEQ No. 470 2df No. 763 SEQ ID ILSLVCLSISIGACAEHSMSR 6-26 for the proteins of SEQ No. 410, 413, 2df No. 764 458 SEQ ID INESR 219-223 for the protein of SEQ No. 349 2d No. 765 SEQ ID INIVK 255-259 for the proteins of SEQ No. 429, 2d No. 766 430, 477; 254-258 for the protein of sequence SEQ ID No. 386 SEQ ID INLYGNALSR 61-70 for the proteins of SEQ No. 366, 374, 2df No. 767 387, 440, 441, 459, 460, 461, 462, 463, 464, 465, 486, 493 SEQ ID IPFSLNLEMK 244-253 for the proteins of SEQ No. 364, 2df No. 768 365, 371, 414, 449, 506 SEQ ID IPHTLFALDADAVR 76-89 for the protein of SEQ No. 373 2d No. 769 SEQ ID IPHTLFALDAGAAR 76-89 for the proteins of SEQ No. 356, 491 2d No. 770 SEQ ID IPHTLFALDAGAVR 76-89 for the proteins of SEQ No. 350, 355, OXA No. 771 363, 367, 370, 375, 415, 443, 481, 488; 65-78 for the protein of sequence SEQ ID No. 362 SEQ ID IPLGK 255-259 for the protein of SEQ No. 379 2df No. 772 SEQ ID IPNAIIGLETGVIK 71-84 for the proteins of SEQ No. 352, 358, OXA No. 773 359, 368, 383, 442, 471, 492, 504; 62-75 for the proteins of sequence SEQ ID No. 348, 353; 72-85 for the protein of sequence SEQ ID No. 490 SEQ ID IPNALIGLETGAIK 71-84 for the proteins of SEQ No. 489, 505 OXA No. 774 SEQ ID IPNSLIAFDTGAVR 78-91 for the protein of SEQ No. 379 2df No. 775 SEQ ID IPSAIIGLETGVIK 71-84 for the proteins of SEQ No. 357, 435, No. 776 501; 62-75 for the protein of sequence SEQ 2de ID No. 354 SEQ ID ISAFNQVK 161-168 for the protein of SEQ No. 489 2d No. 777 SEQ ID ISAHEQILFLR 166-176 for the protein of SEQ No. 373 2d No. 778 SEQ ID ISAMEQTR 160-167 for the protein of SEQ No. 380 2d No. 779 SEQ ID ISAMEQVK 165-172 for the proteins of SEQ No. 429, 2d No. 780 477; 152-159 for the protein of sequence SEQ ID No. 377; 164-171 for the protein of sequence SEQ ID No. 386 SEQ ID ISATEQVAFLR 164-174 for the protein of SEQ No. 384 2df No. 781 SEQ ID ISATQQIAFLR 164-174 for the protein of SEQ No. 485 2df No. 782 SEQ ID ISAVNQVEFLESLFLNK 161-177 for the proteins of SEQ No. 357, OXA No. 783 358, 359, 368, 383, 442, 471, 504; 162-178 for the protein of sequence SEQ ID No. 490 SEQ ID ISAVNQVEFLESLYLNK 161-177 for the proteins of SEQ No. 352, OXA No. 784 435, 492, 501; 152-168 for the proteins of sequence SEQ ID No. 348, 353, 354 SEQ ID ISAVNQVK 161-168 for the protein of SEQ No. 505 2de No. 785 SEQ ID ISPEEQIQFLR 170-180 for the proteins of SEQ No. 360, 2d No. 786 376; 155-165 for the protein of sequence SEQ ID No. 361 SEQ ID ISPEEQVR 166-173 for the protein of SEQ No. 351 2de No. 787 SEQ ID ISPEGQVR 155-162 for the protein of SEQ No. 498 2d No. 788 SEQ ID ISPLEQLAFLR 162-172 for the protein of SEQ No. 433 2d No. 789 SEQ ID ITAFQQVDFLR 188-198 for the protein of SEQ No. 381 2df No. 790 SEQ ID ITLFLLFLNLVFGQDK 4-19 for the protein of SEQ No. 385 2d No. 791 SEQ ID ITPIQEVNFADDFANNR 174-190 for the protein of SEQ No. 447 2df No. 792 SEQ ID ITPIQEVNFADDLANNR 174-190 for the protein of SEQ No. 466 2df No. 793 SEQ ID ITPQQEAQFAYK 173-184 for the proteins of SEQ No. 388, 2df No. 794 389, 390, 391, 392, 393, 394, 395, 396, 397, 398, 399, 400, 401, 402, 403, 404, 406, 407, 408, 409, 411, 412, 416, 417, 418, 419, 420, 421, 422, 423, 424, 425, 426, 427, 428, 434, 436, 437, 438, 439, 444, 445, 446, 448, 451, 452, 453, 454, 455, 456, 457, 467, 468, 472, 473, 474, 475, 478, 479, 480, 482, 483, 487, 495, 502, 503, 507, 508; 167-178 for the proteins of sequence SEQ ID No. 431, 432 SEQ ID ITPQQEAQFTYK 173-184 for the protein of SEQ No. 405 2df No. 795 SEQ ID ITPVQEVNFADDLAHNR 174-190 for the proteins of SEQ No. 364, 2df No. 796 365, 371, 414, 449, 506 SEQ ID IVAFALK 241-247 for the proteins of SEQ No. 366, 387 2df No. 797 SEQ ID IVAFALNMEMR 241-251 for the proteins of SEQ No. 440, 2df No. 798 459, 460, 461, 462, 463, 464, 465, 486, 493; 242-252 for the proteins of sequence SEQ ID No. 374, 441 SEQ ID IVESTTLADGTVVHGK 186-201 for the proteins of SEQ No. 496, 2d No. 799 497, 499, 500 SEQ ID IYNSLIGLNEK 74-84 for the proteins of SEQ No. 386, 429, 2d No. 800 430, 477 SEQ ID KPDIGWWVGWIER 237-249 for the protein of SEQ No. 382 2df No. 801 SEQ ID LACATNNLAR 50-59 for the protein of SEQ No. 490 2d No. 802 SEQ ID LAQGELPFPAPVQSTVR 172-188 for the protein of SEQ No. 380 2d No. 803 SEQ ID LAQNELPYPIEIQK 177-190 for the proteins of SEQ No. 429, 2d No. 804 430, 477 SEQ ID LAQNELQYPIEIQK 176-189 for the protein of SEQ No. 386 2d No. 805 SEQ ID LDFGNK 143-148 for the proteins of SEQ No. 429, 2d No. 806 430, 477; 142-147 for the protein of sequence SEQ ID No. 386 SEQ ID LDGSLNR 206-212 for the protein of SEQ No. 347 2d No. 807 SEQ ID LEIGK 244-248 for the protein of SEQ No. 349 2d No. 808 SEQ ID LEILQQALAELGLYPK 255-270 for the protein of SEQ No. 469 2df No. 809 SEQ ID LENQEQVK 173-180 for the protein of SEQ No. 377 2d No. 810 SEQ ID LETQEEVEK 195-203 for the protein of SEQ No. 364 2df No. 811 SEQ ID LETQEEVK 195-202 for the proteins of SEQ No. 365, 2df No. 812 371, 414, 447, 449, 466, 506 SEQ ID LFAAEGVK 55-62 for the protein of SEQ No. 382 2df No. 813 SEQ ID LFESAGVK 58-65 for the protein of SEQ No. 381 2df No. 814 SEQ ID LFGAAGVK 30-37 for the protein of SEQ No. 380 2d No. 815 SEQ ID LFPEWEK 110-116 for the proteins of SEQ No. 388, 2df No. 816 389, 390, 391, 392, 393, 394, 395, 396, 397, 398, 399, 400, 401, 402, 403, 404, 405, 406, 407, 408, 409, 411, 412, 416, 417, 418, 419, 420, 421, 422, 423, 424, 425, 426, 427, 428, 434, 436, 437, 438, 439, 444, 445, 446, 448, 451, 452, 453, 454, 455, 456, 457, 467, 468, 472, 473, 474, 475, 478, 479, 480, 482, 483, 487, 495, 502, 503, 507, 508; 104-110 for the proteins of sequence SEQ ID No. 431, 432 SEQ ID LGESR 126-130 for the protein of SEQ No. 351 2de No. 817 SEQ ID LGVDR 121-125 for the protein of SEQ No. 349 2d No. 818 SEQ ID LHVSER 181-186 for the proteins of SEQ No. 378, 2df No. 819 384, 450, 476, 485 SEQ ID LHYGNAK 131-137 for the protein of SEQ No. 385 2d No. 820 SEQ ID LLNLLSQSK 160-168 for the protein of SEQ No. 377 2d No. 821 SEQ ID LLQDER 243-248 for the protein of SEQ No. 433 2d No. 822 SEQ ID LLVQDGDCGR 38-47 for the proteins of SEQ No. 496, 497, 2d No. 823 499, 500 SEQ ID LNEVGYGNR 160-168 for the protein of SEQ No. 382 2df No. 824 SEQ ID LNYGNADPSTK 144-154 for the proteins of SEQ No. 355, 363 2d No. 825 SEQ ID LNYGNK 130-135 for the protein of SEQ No. 377 2d No. 826 SEQ ID LPASK 178-182 for the proteins of SEQ No. 489, 2d No. 827 505; 172-176 for the protein of sequence SEQ ID No. 498 SEQ ID LPHTLFALDADAVR 76-89 for the proteins of SEQ No. 369, 372 OXA No. 828 SEQ ID LPHTLFALDAGAVR 76-89 for the protein of SEQ No. 484 OXA No. 829 SEQ ID LPLAIMGFDSGILQSPK 62-78 for the protein of SEQ No. 349 2d No. 830 SEQ ID LPLAIMGYDADILLDATTPR 69-88 for the protein of SEQ No. 351 2de No. 831 SEQ ID LPSSLIALETGAVR 98-111 for the protein of SEQ No. 381 2df No. 832 SEQ ID LPVSAQTLQYTANILK 170-185 for the protein of SEQ No. 347 2d No. 833 SEQ ID LPVSER 205-210 for the protein of SEQ No. 381 2df No. 834 SEQ ID LPVSPTAVDMTER 173-185 for the proteins of SEQ No. 496, 2d No. 835 497, 499, 500 SEQ ID LSASK 178-182 for the proteins of SEQ No. 352, OXA No. 836 357, 358, 359, 368, 383, 435, 442, 471, 492, 501, 504; 169-173 for the proteins of sequence SEQ ID No. 348, 353, 354; 179-183 for the protein of sequence SEQ ID No. 490 SEQ ID LSAVPIYQEVAR 121-132 for the protein of SEQ No. 379 2df No. 837 SEQ ID LSAVPVYQELAR 127-138 for the proteins of SEQ No. 364, 2df No. 838 365, 371, 414, 447, 449, 506; 125-136 for the proteins of sequence SEQ ID No. 366, 374, 387, 440, 441, 459, 460, 461, 462, 463, 464, 465, 486, 493 SEQ ID LSCTLVIDEASGDLLHR 37-53 for the protein of SEQ No. 351 2de No. 839 SEQ ID LSLQHGWFIGWIEK 211-224 for the protein of SEQ No. 494 2de No. 840 SEQ ID LSQNSLPFSQEAMNSVK 164-180 for the protein of SEQ No. 385 2d No. 841 SEQ ID LSVNPK 168-173 for the protein of SEQ No. 494 2de No. 842 SEQ ID LTQDER 239-244 for the proteins of SEQ No. 496, No. 843 497, 499, 500 2d SEQ ID LTVGAR 245-250 for the protein of SEQ No. 351 2de No. 844 SEQ ID LYGFALNIDMPGGEADIGK 228-246 for the protein of SEQ No. 380 2d No. 845 SEQ ID LYHNELPFR 178-186 for the proteins of SEQ No. 356, 491 2d No. 846 SEQ ID LYHNK 176-180 for the proteins of SEQ No. 378, 2df No. 847 384, 450, 476, 485 SEQ ID LYQNDLPFR 178-186 for the protein of SEQ No. 375 2d No. 848 SEQ ID MDDLFK 243-248 for the proteins of SEQ No. 350, OXA No. 849 356, 367, 370, 375, 415, 443, 481, 488, 491; 232-237 for the protein of sequence SEQ ID No. 362 SEQ ID MEDLHK 243-248 for the proteins of SEQ No. 355, 363 2d No. 850 SEQ ID MLIALIGLENHK 85-96 for the protein of SEQ No. 506 2df No. 851 SEQ ID MLLIEQQGDAALYAK 198-212 for the protein of SEQ No. 379 2df No. 852 SEQ ID MLLIK 204-208 for the proteins of SEQ No. 364, 2df No. 853 365, 371, 414, 447, 449, 466, 506 SEQ ID MLNTALIGLEHHK 84-95 for the proteins of SEQ No. 388, 389, 2df No. 854 390, 391, 392, 393, 394, 395, 396, 397, 398, 399, 400, 401, 402, 403, 404, 405, 406, 408, 409, 411, 412, 416, 417, 418, 419, 420, 421, 422, 423, 424, 425, 426, 427, 428, 434, 436, 437, 438, 439, 444, 445, 446, 448, 451, 452, 453, 454, 455, 456, 457, 467, 468, 472, 473, 474, 475, 478, 479, 480, 482, 487, 495, 502, 503, 507, 508; 78-89 for the proteins of sequence SEQ ID No. 431, 432 SEQ ID MLNALIGLENHK 85-96 for the proteins of SEQ No. 364, 365, 2df No. 855 371, 414, 447, 449, 466 SEQ ID MLNALIGLENQK 83-94 for the proteins of SEQ No. 366, 374, 2df No. 856 387, 440, 441, 459, 460, 461, 462, 463, 464, 465, 486, 493 SEQ ID MLNALIGLEYHK 84-95 for the protein of SEQ No. 483 2df No. 857 SEQ ID MLNALIGLQHGK 78-89 for the protein of SEQ No. 469 2df No. 858 SEQ ID MLNALISLEHHK 84-95 for the protein of SEQ No. 407 2df No. 859 SEQ ID MQAYVDAFDYGNR 139-151 for the protein of SEQ No. 379 2df No. 860 SEQ ID MQEGLNK 123-129 for the protein of SEQ No. 377 2d No. 861 SEQ ID MSPASTYK 87-94 for the protein of SEQ No. 382 2df No. 862 SEQ ID MTAGGK 234-239 for the protein of SEQ No. 498 2d No. 863 SEQ ID MVSGK 165-169 for the protein of SEQ No. 347 2d No. 864 SEQ ID NEHDPVLPYR 71-80 for the proteins of SEQ No. 496, 497, 2d No. 865 499, 500 SEQ ID NEHQIFK 86-92 for the protein of SEQ No. 490; 85-91 2d No. 866 for the protein of sequence SEQ ID No. 383 SEQ ID NEHQVFK 85-91 for the proteins of SEQ No. 352, 357, OXA No. 867 358, 359, 368, 435, 442, 471, 492, 501, 504; 76-82 for the proteins of sequence SEQ ID No. 348, 353, 354 SEQ ID NEITYK 262-267 for the proteins of SEQ No. 364, 2df No. 868 365, 371, 414, 447, 449, 466, 506 SEQ ID NELLMK 260-265 for the proteins of SEQ No. 366, 2df No. 869 387, 440, 459, 460, 462, 463, 464, 465, 486, 493; 261-266 for the proteins of sequence SEQ ID No. 374, 441 SEQ ID NELMMK 260-265 for the protein of SEQ No. 461 2df No. 870 SEQ ID NELPFR 181-186 for the proteins of SEQ No. 350, OXA No. 871 355, 356, 363, 367, 370, 415, 443, 481, 488, 491; 170-175 for the protein of sequence SEQ ID No. 362 SEQ ID NFILIFIFVILISCK 5-19 for the proteins of SEQ No. 386, 429, 2d No. 872 477 SEQ ID NFILIFIFVILTSCK 5-19 for the protein of SEQ No. 430 2d No. 873 SEQ ID NISSYGNNLVR 62-72 for the protein of SEQ No. 466 2df No. 874 SEQ ID NISTYGNNLTR 62-72 for the protein of SEQ No. 447 2df No. 875 SEQ ID NLFNEVHTTGVLVIR 43-57 for the protein of SEQ No. 412 2df No. 876 SEQ ID NLSTYGNALAR 62-72 for the proteins of SEQ No. 364, 365, 2df No. 877 371, 414, 449, 506 SEQ ID NMENLELFGK 187-196 for the protein of SEQ No. 385 2d No. 878 SEQ ID NMLLLEENNGYK 201-212 for the protein of SEQ No. 440 2df No. 879 SEQ ID NMLLLEESNGYK 201-212 for the proteins of SEQ No. 366, 2df No. 880 374, 387, 441, 459, 460, 461, 462, 463, 465, 486, 493 SEQ ID NMLLLEK 201-207 for the protein of SEQ No. 464 2df No. 881 SEQ ID NMTLGDAMK 117-125 for the proteins of SEQ No. 388, 2df No. 882 392, 393, 396, 397, 402, 405, 406, 416, 419, 422, 424, 434, 445, 446, 448, 475, 503; 111-119 for the proteins of sequence SEQ ID No. 431, 432 SEQ ID NNGLTEAWLESSLK 156-169 for the proteins of SEQ No. 360, 2d No. 883 376; 141-154 for the protein of sequence SEQ ID No. 361 SEQ ID NQLPFK 181-186 for the protein of SEQ No. 373 2d No. 884 SEQ ID NQLPFQVEHQR 181-191 for the proteins of SEQ No. 369, OXA No. 885 372, 484 SEQ ID NSAIENTIDNMYLQDLENSTK 191-211 for the protein of SEQ No. 376 2d No. 886 SEQ ID NSAIENTIENMYLQDLDNSTK 191-211 for the protein of SEQ No. 360 2d No. 887 SEQ ID NSAIENTIENMYLQDLENSTK 176-196 for the protein of SEQ No. 361 2d No. 888 SEQ ID NSAVWVYELFAK 119-130 for the proteins of SEQ No. 369, OXA No. 889 372, 484 SEQ ID NSQVPAYK 118-125 for the proteins of SEQ No. 429, 2d No. 890 430, 477; 117-124 for the protein of sequence SEQ ID No. 386 SEQ ID NSTVWIYELFAK 119-130 for the proteins of SEQ No. 356, 491 2d No. 891 SEQ ID NSTVWVYELFAK 119-130 for the proteins of SEQ No. 350, OXA No. 892 367, 370, 373, 375, 415, 443, 481, 488; 108-119 for the protein of sequence SEQ ID No. 362 SEQ ID NSTVWVYQLFAK 119-130 for the proteins of SEQ No. 355, 363 2d No. 893 SEQ ID NTSGALVIQTDK 48-59 for the protein of SEQ No. 460 2df No. 894 SEQ ID NTSGVLVIQTDK 48-59 for the proteins of SEQ No. 366, 374, 2df No. 895 387, 440, 441, 459, 461, 462, 463, 464, 465, 486, 493 SEQ ID NVDEMFYYYDGSK 75-87 for the protein of SEQ No. 377 2d No. 896 SEQ ID NWILR 204-208 for the proteins of SEQ No. 350, OXA No. 897 356, 367, 369, 370, 372, 375, 415, 443, 481, 484, 488, 491; 193-197 for the protein of sequence SEQ ID No. 362 SEQ ID NWNAAMDLR 125-133 for the protein of SEQ No. 382 2df No. 898 SEQ ID NYVDAFHYGNQDISGDK 118-134 for the protein of SEQ No. 494 2de No. 899 SEQ ID QADHAILVFDQAR 51-63 for the protein of SEQ No. 375 2d No. 900 SEQ ID QAEHALLVFGQER 51-63 for the proteins of SEQ No. 369, 372, OXA No. 901 484 SEQ ID QAITK 251-255 for the proteins of SEQ No. 378, 2df No. 902 384, 450, 485; 247-251 for the protein of sequence SEQ ID No. 476 SEQ ID QAMLTEANSDYIIR 193-206 for the protein of SEQ No. 384 2df No. 903 SEQ ID QEVQFVSALAR 171-181 for the protein of SEQ No. 469 2df No. 904 SEQ ID QFASIK 243-248 for the protein of SEQ No. 347 2d No. 905 SEQ ID QGMPGSIR 254-261 for the protein of SEQ No. 447 2df No. 906 SEQ ID QGMSGSIR 254-261 for the protein of SEQ No. 466 2df No. 907 SEQ ID QGQTQQSYGNDLAR 58-71 for the proteins of SEQ No. 388, 389, 2df No. 908 390, 391, 392, 393, 394, 395, 396, 397, 398, 399, 400, 401, 402, 403, 404, 405, 406, 407, 408, 409, 411, 412, 416, 417, 418, 419, 420, 421, 422, 423, 424, 425, 426, 427, 428, 436, 437, 438, 439, 444, 445, 446, 448, 451, 452, 453, 454, 455, 456, 457, 467, 468, 472, 473, 474, 475, 478, 479, 480, 482, 483, 487, 495, 502, 503, 507, 508; 52-65 for the proteins of sequence SEQ ID No. 431, 432 SEQ ID QIDYGNADPSTIK 143-155 for the proteins of SEQ No. 369, OXA No. 909 372, 484 SEQ ID QIDYGNVDPSTIK 143-155 for the protein of SEQ No. 373 2d No. 910 SEQ ID QIGEAR 129-134 for the proteins of SEQ No. 378, 2df No. 911 450, 476, 485 SEQ ID QIGQAR 129-134 for the protein of SEQ No. 384 2df No. 912 SEQ ID QIMLIEQTPAFTLR 190-203 for the protein of SEQ No. 470 2df No. 913 SEQ ID QLGSAIDQFWLR 152-163 for the protein of SEQ No. 379 2df No. 914 SEQ ID QLHDNK 199-204 for the protein of SEQ No. 381 2df No. 915 SEQ ID QLIFVHTVVQK 229-239 for the protein of SEQ No. 347 2d No. 916 SEQ ID QLIFVHTVVQKPGK 229-242 for the protein of SEQ No. 347 2d No. 917 SEQ ID QLPVK 178-182 for the protein of SEQ No. 433; 184-188 OXA No. 918 for the protein of sequence SEQ ID No. 379 SEQ ID QLPVKPR 184-190 for the protein of SEQ No. 379 2df No. 919 SEQ ID QLSLDVLDK 265-273 for the proteins of SEQ No. 410, 2df No. 920 413, 458 SEQ ID QLVYAR 237-242 for the protein of SEQ No. 433 2d No. 921 SEQ ID QMMLTEASTDYIIR 217-230 for the protein of SEQ No. 381 2df No. 922 SEQ ID QMSIVEATPDYVLHGK 214-229 for the protein of SEQ No. 382 2df No. 923 SEQ ID QPTDPAR 99-105 for the protein of SEQ No. 433 2d No. 924 SEQ ID QPTDPTR 93-99 for the proteins of SEQ No. 496, 497, 2d No. 925 499, 500 SEQ ID QPVSAGIR 246-253 for the proteins of SEQ No. 496, 2d No. 926 497, 499, 500 SEQ ID QQLVK 275-279 for the protein of SEQ No. 381 2df No. 927 SEQ ID QTLVFAR 232-238 for the proteins of SEQ No. 496, 2d No. 928 497, 499, 500 SEQ ID QVGAEK 126-131 for the protein of SEQ No. 470 2df No. 929 SEQ ID QVVFAR 238-243 for the protein of SEQ No. 349 2d No. 930 SEQ ID SADEVLPYGGK 84-94 for the protein of SEQ No. 380 2d No. 931 SEQ ID SADEVLPYGGKPQR 84-97 for the protein of SEQ No. 380 2d No. 932 SEQ ID SCATNDLAR 50-58 for the proteins of SEQ No. 352, 435, OXA No. 933 492, 501; 41-49 for the proteins of sequence SEQ ID No. 348, 353, 354 SEQ ID SCATNNLAR 50-58 for the proteins of SEQ No. 357, 358, OXA No. 934 359, 368, 383, 442, 471, 504 SEQ ID SDIPGGSK 251-258 for the protein of SEQ No. 349 2d No. 935 SEQ ID SDWGK 29-33 for the protein of SEQ No. 375 2d No. 936 SEQ ID SEDNFHISSQQHEK 27-40 for the proteins of SEQ No. 364, 365, 2df No. 937 371, 414, 449, 506 SEQ ID SEMPASIR 252-259 for the proteins of SEQ No. 366, 2df No. 938 387, 440, 459, 460, 461, 462, 463, 464, 486, 493; 253-260 for the proteins of sequence SEQ ID No. 374, 441 SEQ ID SEMPASTR 252-259 for the protein of SEQ No. 465 2df No. 939 SEQ ID SFAAHNQDQDLR 103-114 for the proteins of SEQ No. 356, 491 2d No. 940 SEQ ID SFAGHNK 103-109 for the protein of SEQ No. 375 2d No. 941 SEQ ID SFAGHNQDQDLR 103-114 for the proteins of SEQ No. 369, 2d No. 942 372, 373, 484 SEQ ID SFAGHNQDQNLR 103-114 for the proteins of SEQ No. 355, 363 2d No. 943 SEQ ID SFLESWAK 100-107 for the protein of SEQ No. 386 2d No. 944 SEQ ID SFTAWEK 109-115 for the proteins of SEQ No. 366, 2df No. 945 374, 387, 441, 459, 460, 461, 462, 463, 464, 465, 486, 493; 104-110 for the protein of sequence SEQ ID No. 469 SEQ ID SFTTWEK 109-115 for the protein of SEQ No. 440 2df No. 946 SEQ ID SGSGWLR 207-213 for the protein of SEQ No. 349 2d No. 947 SEQ ID SGWGMAVDPQVGWYVGFVEK 221-240 for the proteins of SEQ No. 410, 2df No. 948 413, 458 SEQ ID SGWGMDVSPQVGWLTGWVEK 219-238 for the protein of SEQ No. 466 2df No. 949 SEQ ID SGWGMDVTPQVGWLTGWVEK 219-238 for the protein of SEQ No. 447 2df No. 950 SEQ ID SIHPASTFK 69-77 for the protein of SEQ No. 379 2df No. 951 SEQ ID SIPTK 252-256 for the proteins of SEQ No. 352, OXA No. 952 357, 358, 359, 368, 383, 435, 442, 471, 490, 492, 501, 504, 505; 243-247 for the proteins of sequence SEQ ID No. 348, 353, 354 SEQ ID SISTK 252-256 for the protein of SEQ No. 489 2d No. 953 SEQ ID SLGLSNNLSR 76-85 for the protein of SEQ No. 381 2df No. 959 SEQ ID SLSMSGK 4-10 for the protein of SEQ No. 351 2de No. 955 SEQ ID SMLFIEEK 202-209 for the proteins of SEQ No. 388, 2df No. 956 389, 390, 391, 392, 393, 394, 395, 396, 397, 398, 399, 400, 401, 402, 403, 404, 405, 406, 407, 408, 409, 411, 416, 417, 418, 419, 420, 421, 422, 424, 425, 426, 427, 428, 434, 436, 437, 438, 439, 444, 445, 446, 451, 452, 453, 454, 455, 456, 457, 467, 468, 472, 473, 474, 475, 478, 479, 480, 482, 483, 487, 495, 502, 503, 507, 508; 196-203 for the proteins of sequence SEQ ID No. 431, 432 SEQ ID SNGEK 239-243 for the proteins of SEQ No. 447, 466 2df No. 957 SEQ ID SNGLTHSWLGSSLK 141-154 for the protein of SEQ No. 498 2d No. 958 SEQ ID SNGYK 208-212 for the proteins of SEQ No. 366, 2df No. 959 374, 387, 441, 459, 460, 461, 462, 463, 464, 465, 486, 493 SEQ ID SPTWELK 79-85 for the protein of SEQ No. 349 2d No. 960 SEQ ID SPTWELKPEYNPSPR 79-93 for the protein of SEQ No. 349 2d No. 961 SEQ ID SQDIVR 208-213 for the protein of SEQ No. 382 2df No. 962 SEQ ID SQQKPTDPTIWLK 100-112 for the protein of SEQ No. 351 2de No. 963 SEQ ID SQVGWLTGWVEQPDGK 225-240 for the protein of SEQ No. 486 2df No. 969 SEQ ID SSSNSCTTNNAAR 46-58 for the protein of SEQ No. 489 2d No. 965 SEQ ID SSSNSCTTNNATR 46-58 for the protein of SEQ No. 505 2de No. 966 SEQ ID SVYGELR 139-145 for the protein of SEQ No. 470 2df No. 967 SEQ ID SWILR 204-208 for the protein of SEQ No. 373 2d No. 968 SEQ ID SYFDEAQTQGVIIIK 44-58 for the proteins of SEQ No. 364, 365, 2df No. 969 371, 414, 447, 449, 466, 506 SEQ ID SYLEK 139-143 for the proteins of SEQ No. 355, 363 2d No. 970 SEQ ID SYPMWEK 111-117 for the proteins of SEQ No. 447, 466 2df No. 971 SEQ ID TAYIPASTFK 61-70 for the proteins of SEQ No. 489, 505; 2df No. 972 77-86 for the proteins of sequence SEQ ID No. 410, 413, 458 SEQ ID TDDLFK 243-248 for the proteins of SEQ No. 369, 2d No. 973 372, 373, 484 SEQ ID TDINEIFK 95-102 for the proteins of SEQ No. 374, 387, 2df No. 974 440, 441, 459, 460, 461, 462, 463, 464, 465, 486, 493 SEQ ID TFIHNDPR 51-58 for the protein of SEQ No. 470 2df No. 975 SEQ ID TGAGFTANR 216-224 for the proteins of SEQ No. 360, 2d No. 976 376; 201-209 for the protein of sequence SEQ ID No. 361 SEQ ID TGFNDGQK 197-204 for the protein of SEQ No. 385 2d No. 977 SEQ ID TGLADSK 210-216 for the proteins of SEQ No. 429, 2d No. 978 430; 209-215 for the protein of sequence SEQ ID No. 386 SEQ ID TGLDLMQK 140-147 for the protein of SEQ No. 447 2df No. 979 SEQ ID TGLELMQK 140-147 for the proteins of SEQ No. 364, 2df No. 980 365, 371, 414, 449, 506 SEQ ID TGMGYPK 198-204 for the protein of SEQ No. 347 2d No. 981 SEQ ID TGNGR 197-201 for the protein of SEQ No. 494 2de No. 982 SEQ ID TGTGSFIDAR 200-209 for the protein of SEQ No. 498 2d No. 983 SEQ ID TGTGSLSDAK 211-220 for the protein of SEQ No. 351 2de No. 984 SEQ ID TGVATEYQPEIGWWAGWVER 213-232 for the protein of SEQ No. 379 2df No. 985 SEQ ID TGVSYPLLADGTR 202-214 for the proteins of SEQ No. 496, 2d No. 986 497, 499, 500 SEQ ID TGWAAMDIK 217-225 for the proteins of SEQ No. 374, 441 2df No. 987 SEQ ID TGWAMDIK 217-224 for the proteins of SEQ No. 366, 2df No. 988 387, 440, 460, 461, 462, 463, 464, 465, 486, 493 SEQ ID TGWAMDVK 217-224 for the protein of SEQ No. 459 2df No. 989 SEQ ID TGWATR 206-211 for the protein of SEQ No. 470 2df No. 990 SEQ ID TGWCFDCTPELGWWVGWVK 205-223 for the protein of SEQ No. 380 2d No. 991 SEQ ID TGWEGR 211-216 for the proteins of SEQ No. 350, OXA No. 992 356, 367, 369, 370, 372, 373, 415, 443, 481, 484, 488, 491; 200-205 for the protein of sequence SEQ ID No. 362 SEQ ID TGWFVDK 230-236 for the protein of SEQ No. 382 2df No. 993 SEQ ID TGYDTK 209-214 for the protein of SEQ No. 476 2df No. 994 SEQ ID TGYGVR 233-238 for the protein of SEQ No. 381 2df No. 995 SEQ ID TGYSAR 209-214 for the protein of SEQ No. 450 2df No. 996 SEQ ID TGYSTR 209-214 for the proteins of SEQ No. 378, 2df No. 997 384, 485 SEQ ID THESSNWGK 25-33 for the proteins of SEQ No. 355, 363 2d No. 998 SEQ ID TICTAIADAGTGK 25-37 for the proteins of SEQ No. 496, 497, 2d No. 999 499, 500 SEQ ID TIGGAPDAYWVDDSLQISAR 169-188 for the protein of SEQ No. 382 2df No. 1000 SEQ ID TLPFSASSYETLR 177-189 for the protein of SEQ No. 470 2df No. 1001 SEQ ID TLPFSLK 189-195 for the proteins of SEQ No. 399, 2df No. 1002 403, 411 SEQ ID TLPFSPK 189-195 for the proteins of SEQ No. 389, 2df No. 1003 395, 412, 423, 428, 439, 445, 467, 482, 483, 495 SEQ ID TLPFSQEVQDEVQSILFIEEK 189-209 for the protein of SEQ No. 448 2df No. 1004 SEQ ID TLPFSQEVQDEVQSMLFIEEK 189-209 for the proteins of SEQ No. 392, 434 2df No. 1005 SEQ ID TLPFSQK 189-195 for the proteins of SEQ No. 388, 2df No. 1006 390, 391, 393, 394, 396, 397, 398, 400, 401, 402, 404, 405, 406, 407, 408, 409, 416, 417, 418, 419, 420, 421, 422, 424, 425, 426, 427, 436, 437, 438, 444, 446, 451, 452, 453, 454, 455, 456, 457, 468, 472, 473, 474, 475, 478, 480, 487, 502, 503, 507, 508; 183-189 for the proteins of sequence SEQ ID No. 431, 432 SEQ ID TLPSSQK 189-195 for the protein of SEQ No. 479 2df No. 1007 SEQ ID TLQNGWFEGFIISK 225-238 for the proteins of SEQ No. 360, 2d No. 1008 376; 210-223 for the protein of sequence SEQ ID No. 361 SEQ ID TMQEYLNK 123-130 for the protein of SEQ No. 385 2d No. 1009 SEQ ID TNGNSTSVYNESR 51-63 for the proteins of SEQ No. 355, 363 2d No. 1010 SEQ ID TQTYQAYDAAR 72-82 for the protein of SEQ No. 382 2df No. 1011 SEQ ID TTDPTIWEK 93-101 for the protein of SEQ No. 498 2d No. 1012 SEQ ID TTTTEVFK 96-103 for the proteins of SEQ No. 395, 428 2df No. 1013 SEQ ID TWASNDFSR 41-49 for the protein of SEQ No. 385 2d No. 1014 SEQ ID TWDMVQR 191-197 for the protein of SEQ No. 379 2df No. 1015 SEQ ID TWMQFSVVWVSQEITQK 113-129 for the proteins of SEQ No. 360, 2d No. 1016 376; 98-114 for the protein of sequence SEQ ID No. 361 SEQ ID TYPMWEK 111-117 for the proteins of SEQ No. 364, 2df No. 1017 365, 371, 414, 449, 506 SEQ ID TYVVDPAR 58-65 for the protein of SEQ No. 379 2df No. 1018 SEQ ID VAFSLNIEMK 244-253 for the protein of SEQ No. 447 2df No. 1019 SEQ ID VANSLIGLSTGAVR 70-83 for the protein of SEQ No. 380 2d No. 1020 SEQ ID VEHQR 187-191 for the proteins of SEQ No. 350, OXA No. 1021 355, 356, 363, 367, 369, 370, 372, 373, 375, 415, 443, 481, 484, 488, 491; 176-180 for the protein of sequence SEQ ID No. 362 SEQ ID VELGK 248-252 for the protein of SEQ No. 380 2d No. 1022 SEQ ID VEDDAGVSGTFVLMDITADR 38-57 for the protein of SEQ No. 379 2df No. 1023 SEQ ID VFLDSWAK 88-95 for the protein of SEQ No. 377 2d No. 1024 SEQ ID VFLESWAK 101-108 for the proteins of SEQ No. 429, 2d No. 1025 430, 477 SEQ ID VFLSSWAQDMNLSSAIK 89-105 for the protein of SEQ No. 385 2d No. 1026 SEQ ID VGFER 134-138 for the protein of SEQ No. 379 2df No. 1027 SEQ ID VILVFDQVR 55-63 for the proteins of SEQ No. 356, 491 2d No. 1028 SEQ ID VITFTK 228-233 for the protein of SEQ No. 494 2de No. 1029 SEQ ID VMAAMVR 158-164 for the protein of SEQ No. 381 2df No. 1030 SEQ ID VPLAVMGYDAGILVDAHNPR 58-77 for the protein of SEQ No. 498 2d No. 1031 SEQ ID VQANVK 195-200 for the proteins of SEQ No. 366, 2df No. 1032 374, 387, 440, 441, 459, 460, 461, 462, 463, 464, 465, 486, 493 SEQ ID VQDEVK 196-201 for the protein of SEQ No. 444 2df No. 1033 SEQ ID VQDEVQSMLFIEEK 196-209 for the proteins of SEQ No. 388, 2df No. 1034 389, 390, 391, 392, 393, 395, 396, 397, 398, 399, 400, 401, 402, 404, 405, 406, 407, 408, 409, 411, 416, 417, 418, 419, 420, 421, 422, 424, 425, 426, 427, 428, 434, 436, 437, 438, 439, 445, 446, 451, 452, 453, 454, 455, 457, 467, 468, 472, 473, 474, 475, 478, 479, 480, 482, 483, 487, 495, 502, 503, 507, 508; 190-203 for the proteins of sequence SEQ ID No. 431, 432 SEQ ID VQDEVQSMLFIEEMNGNK 196-213 for the proteins of SEQ No. 412, 423 2df No. 1035 SEQ ID VQDGVQSMLFIEEK 196-209 for the protein of SEQ No. 456 2df No. 1036 SEQ ID VQHEVQSMLFIEEK 196-209 for the protein of SEQ No. 394 2df No. 1037 SEQ ID VSCLPCYQVVSHK 138-150 for the protein of SEQ No. 382 2df No. 1038 SEQ ID VSCVWCYQALAR 114-125 for the protein of SEQ No. 470 2df No. 1039 SEQ ID VSDVCSEVTAEGWQEVR 37-53 for the protein of SEQ No. 381 2df No. 1040 SEQ ID VSEVEGWQIHGK 186-197 for the protein of SEQ No. 347 2d No. 1041 SEQ ID VSFSLNIEMK 244-253 for the protein of SEQ No. 466 2df No. 1042 SEQ ID VSPCSSFK 54-61 for the protein of SEQ No. 349 2d No. 1043 SEQ ID VSQVPAYK 105-112 for the protein of SEQ No. 377 2d No. 1044 SEQ ID VVFAR 229-233 for the protein of SEQ No. 498; 239-243 OXA No. 1045 for the proteins of sequence SEQ ID No. 349.351 SEQ ID WDGAK 97-101 for the proteins of SEQ No. 355, 363 2d No. 1046 SEQ ID WDGEK 104-108 for the proteins of SEQ No. 393, 2df No. 1047 402, 419, 422, 424 SEQ ID WDGHIYDFPDWNR 92-104 for the protein of SEQ No. 470 2df No. 1048 SEQ ID WDGIK 97-101 for the proteins of SEQ No. 356, 491 2d No. 1049 SEQ ID WDGKPR 92-97 for the proteins of SEQ No. 352, 357, OXA No. 1050 358, 359, 368, 383, 435, 442, 471, 489, 492, 501, 504, 505; 83-88 for the proteins of sequence SEQ ID No. 348, 353, 354; 107-112 for the proteins of sequence SEQ ID No. 410, 413, 458; 93-98 for the protein of sequence SEQ ID No. 490; 116-121 for the protein of sequence SEQ ID No. 382; SEQ ID WDGQK 104-108 for the proteins of SEQ No. 388, 2df No. 1051 389, 392, 395, 396, 397, 399, 403, 405, 406, 407, 411, 412, 423, 428, 434, 439, 445, 446, 448, 467, 468, 482, 483, 495, 503, 508; 98-102 for the proteins of sequence SEQ ID No. 431, 432 SEQ ID WDGQTR 95-100 for the proteins of SEQ No. 378, 384, 2df No. 1052 450, 476, 485 SEQ ID WDGVK 97-101 for the proteins of SEQ No. 369, 372, 2d No. 1053 375, 484 SEQ ID WDGVNR 97-102 for the proteins of SEQ No. 350, 367, OXA No. 1054 370, 373, 415, 443, 481, 488; 86-91 for the protein of sequence SEQ ID No. 362 SEQ ID WDYKPEFNGYK 78-88 for the protein of SEQ No. 498; 89-99 OXA No. 1055 for the protein of sequence SEQ ID No. 351 SEQ ID WETYSVVWFSQQITEWLGMER 97-117 for the protein of SEQ No. 347 2d No. 1056 SEQ ID WNGQK 104-108 for the proteins of SEQ No. 394, 2df No. 1057 418, 444, 507 SEQ ID YAQAK 155-159 for the protein of SEQ No. 382 2df No. 1058 SEQ ID YFSDFNAK 34-41 for the proteins of SEQ No. 355, 363 2d No. 1059 SEQ ID YGTHLDR 68-74 for the proteins of SEQ No. 410, 413, 2df No. 1060 458 SEQ ID YIIHNK 54-59 for the proteins of SEQ No. 386, 429, 2d No. 1061 430, 477 SEQ ID YLDELVK 245-251 for the protein of SEQ No. 385 2d No. 1062 SEQ ID YLMITEAGR 195-203 for the protein of SEQ No. 484 OXA No. 1063 SEQ ID YLNLFSYGNANIGGGIDK 135-152 for the proteins of SEQ No. 489, 505 OXA No. 1064 SEQ ID YNGEK 96-100 for the proteins of SEQ No. 429, 430, 2d No. 1065 477 SEQ ID YPHNPR 88-93 for the protein of SEQ No. 494 2de No. 1066 SEQ ID YPVVWYSQQVAHHLGAQR 103-120 for the protein of SEQ No. 497 2d No. 1067 SEQ ID YSNVLAFK 106-113 for the protein of SEQ No. 385 2d No. 1068 SEQ ID YSPASTFK 68-75 for the proteins of SEQ No. 350, 355, OXA No. 1069 356, 363, 367, 369, 370, 372, 373, 375, 415, 443, 481, 484, 488, 491; 57-64 for the protein of sequence SEQ ID No. 362 SEQ ID YSVVPVYQQLAR 141-152 for the protein of SEQ No. 381 2df No. 1070 SEQ ID YSVVWYSQLTAK 109-120 for the protein of SEQ No. 433 2d No. 1071 SEQ ID YSVVWYSQQVAHHLGAQR 103-120 for the proteins of SEQ No. 496, 2d No. 1072 499, 500 SEQ ID YTPASTFK 55-62 for the protein of SEQ No. 433 2d No. 1073 SEQ ID YTSAFGYGNADVSGEPGK 130-147 for the protein of SEQ No. 433 2d No. 1074 SEQ ID YVFVSALTGNLGSNLTSSIK 228-247 for the protein of SEQ No. 361; 243-262 2d No. 1075 for the protein of sequence SEQ ID No. 360 SEQ ID YVFVSALTGSLGSNLTSSIK 243-262 for the protein of SEQ No. 376 2d No. 1076 SEQ ID YVGHDR 50-55 for the protein of SEQ No. 380 2d No. 1077 SEQ ID ANQAFLPASTFK 62-73 for the proteins of SEQ No. 378, 384, 2df No. 1098 450, 476, 485 SEQ ID DEHQVFK 88-94 for the proteins of SEQ No. 378, 384, 2df No. 1099 450, 476, 485 SEQ ID DHNLITAMK 108-116 for the proteins of SEQ No. 378, 2df No. 1100 450, 476 SEQ ID DIATWNR 101-107 for the proteins of SEQ No. 378, 2df No. 1101 450, 476 SEQ ID IPNSLIALDLGVVK 74-87 for the proteins of SEQ No. 378, 384, 2df No. 1102 450, 476, 485 SEQ ID ISATEQISFLR 164-174 for the proteins of SEQ No. 378, 2df No. 1103 450, 476 SEQ ID QAMLTEANGDYIIR 193-206 for the proteins of SEQ No. 378, 2df No. 1104 450, 476, 485 SEQ ID QQGFTNNLK 52-60 for the proteins of SEQ No. 378, 384, 2df No. 1105 450, 476, 485 SEQ ID SQGVVVLWNENK 40-51 for the proteins of SEQ No. 378, 450, 2df No. 1106 476, 485 SEQ ID SWNAHFTEHK 30-39 for the proteins of SEQ No. 378, 450, 2df No. 1107 476, 485 SEQ ID VLALSAVFLVASIIGMPAVAK 3-23 for the proteins of SEQ No. 378, 450, 2df No. 1108 476, 485 SEQ ID YSVVPVYQEFAR 117-128 for the proteins of SEQ No. 378, 2df No. 1109 384, 450, 476, 485

In the clinical interest column, the entries 2d, 2de, 2df correspond to the functional subgroups of OXA beta-lactamases which the corresponding peptide makes it possible to detect. Therefore, the detection of a 2df peptide will indicate the presence of a carbapenemase beta-lactamase capable of hydrolysing carbapenems.

The entry 2de will indicate the presence of a beta-lactamase with an extended spectrum (ESBL) capable of hydrolysing penicillins, first-generation cephalosporins such as cephaloridine and cefalotin, and at least one antibiotic from the oxyimino-beta-lactam class such as cefotaxime, ceftazidime or monobactams such as aztreonam.

The entry OXA indicates a common peptide between at least two of the subgroups 2d, 2de and 2df. The corresponding peptide indicates the presence of an OXA beta-lactamase and the presence of a mechanism of resistance at least to penicillins and to first-generation cephalosporins.

The detection of a mechanism of resistance to carbapenems induced by an OXA protein is characterised by the detection of at least one resistance-marking carba peptide chosen from the sequences SEQ ID No. 510, 511, 512, 513, 514, 520, 521, 522, 523, 525, 527, 530, 532, 537, 541, 542, 543, 544, 545, 546, 547, 548, 549, 550, 551, 552, 556, 557, 558, 559, 560, 561, 562, 574, 579, 581, 582, 583, 584, 592, 596, 597, 598, 599, 600, 601, 602, 607, 608, 609, 628, 631, 632, 633, 635, 636, 644, 646, 647, 649, 650, 655, 656, 661, 662, 667, 674, 675, 682, 689, 690, 698, 713, 714, 719, 720, 722, 727, 729, 730, 741, 746, 748, 750, 751, 752, 755, 756, 757, 758, 763, 764, 767, 768, 772, 775, 781, 782, 790, 792, 793, 794, 795, 796, 797, 798, 801, 809, 811, 812, 813, 814, 816, 819, 824, 832, 834, 837, 838, 847, 851, 852, 853, 854, 855, 856, 857, 858, 859, 860, 862, 868, 869, 870, 874, 875, 876, 877, 879, 880, 881, 882, 894, 895, 898, 902, 903, 904, 906, 907, 908, 911, 912, 913, 914, 915, 919, 920, 922, 923, 927, 929, 937, 938, 939, 945, 946, 948, 949, 950, 951, 954, 956, 957, 959, 962, 964, 967, 969, 971, 972, 974, 975, 979, 980, 985, 988, 990, 993, 994, 995, 996, 997, 1000, 1001, 1002, 1003, 1004, 1005, 1006, 1007, 1011, 1013, 1015, 1017, 1018, 1019, 1023, 1027, 1030, 1032, 1033, 1034, 1035, 1036, 1037, 1038, 1039, 1040, 1042, 1047, 1048, 1051, 1052, 1057, 1058, 1060, 1070, 1098, 1099, 1100, 1101, 1102, 1103, 1104, 1105, 1106, 1107, 1108, 1109

Certain peptide sequences can be common to several resistance mechanisms. Therefore, the following sequences are identical:

SEQ ID No. 24 and SEQ ID No. 287

In all cases, the sequences above indicate the expression of a mechanism of resistance to penicillins, to cephalosporins, including those of the third generation such as cefotaxime/ceftazidime, to monobactams and to carbapenems.

The method of the invention and its advantages will become apparent from the rest of the present description which presents several non-limiting examples of implementation of said method.

EXAMPLE 1 Identification of Microorganisms from a Sample by Biochemical Profile

1. Culturing of the Sample on a Culture Medium

The optimum culture media and the optimum culture conditions are different according to the species of microorganism. By default, the sample is seeded on different media:

-   -   sheep blood Columbia agar (bioMérieux ref. 43041) for 18 to 24 h         at 35° C., in an aerobic or anaerobic atmosphere;     -   TSA agar (bioMérieux ref. 43011) for 18 to 24 h at 37° C.

2. Identification of the Microorganisms

The identification is performed as follows:

-   -   1. Selection of isolated colonies     -   2. While maintaining the aseptic conditions, transfer of 3.0 mL         of aqueous sterile saline solution (0.45-0.50% NaCl, pH 4.5 to         7.0) into a transparent plastic (polystyrene) test tube     -   3. With the aid of a stirrer or a sterile swab, transfer of a         sufficient number of identical colonies into the saline solution         tube prepared in step 2, and adjustment of the bacterial         suspension between 0.50 and 0.63 McFarland with a calibrated         DENSICHEK from VITEK®     -   4. Positioning of the bacterial suspension tube and of a VITEK®         identification card on a VITEK® cartridge     -   5. Loading of the cartridge into the VITEK® instrument     -   6. The filling, sealing, incubation and reading operations are         automatic     -   7. Acquisition of a biochemical profile     -   8. Identification with the VITEK® system performed by comparing         to the biochemical profiles of known strains

EXAMPLE 2 Preparation of a Primary Urine Sample by Microorganism Enrichment

The following protocol is performed in 16 steps (steps 5 to 12 are optional and could be omitted if the enriched sample is subsequently treated according to examples 4 and onwards):

-   -   1. Centrifuging of 5 mL of contaminated urine, at 2000 g for 30         seconds     -   2. Recovery of the supernatant     -   3. Centrifuging at 15000 g for 5 minutes     -   4. Elimination of the supernatant     -   5. Washing of the pellet with 3 mL of distilled water by         resuspension     -   6. Centrifuging at 15000 g for 5 minutes     -   7. Elimination of the supernatant     -   8. Place the pellet in the presence of solvent (8 acetone         volumes for 1 methanol volume) for 1/10 dilution     -   9. Leave for 1 hour at −20° C.     -   10. Centrifuging at 15000 g for 5 minutes     -   11. Elimination of the supernatant     -   12. Place the pellet in the presence of solvent (8 acetone         volumes for 1 methanol volume) for 1/10 dilution     -   13. Leave for 1 hour at −20° C.     -   14. Centrifuging at 15000 g for 5 minutes     -   15. Elimination of the supernatant     -   16. The pellet constitutes the microorganism-enriched sample

EXAMPLE 3 Identification of Microorganisms from a Sample by MALDI-TOF

The identification is performed as follows:

-   -   1. Transfer, with the aid of a 1 μl oese, of a portion of         microorganism colony obtained according to Example 1, or of an         enriched sample according to Example 2, and uniform deposition         on a plate for MALDI-TOF mass spectrometry     -   2. Covering the deposit with 1 μl of matrix. The matrix used is         a saturated solution of HCCA (alpha-cyano-4-hydroxycinnamic         acid) in organic solvent (50% acetonitrile and 2.5%         trifluoroacetic acid)     -   3. Drying at ambient temperature     -   4. Introducing the plate into the mass spectrometer     -   5. Acquiring a mass spectrum     -   6. Comparing the obtained spectrum with the spectra contained in         a knowledge base     -   7. Identification of the microorganism by comparing the obtained         peaks with those in the knowledge base

EXAMPLE 4 Identification of Microorganisms from a Sample by ESI-TOF

The identification is performed as follows:

-   -   1. Sampling of a microorganism colony, obtained according to         Example 1, or of an enriched sample according to Example 2, and         suspension in 100 μl of demineralised water.     -   2. Centrifuging at 3000 g for 5 minutes.     -   3. Elimination of the supernatant.     -   4. Resuspension in 100 μl of demineralised water.     -   5. Centrifuging at 3000 g for 5 minutes.     -   6. Elimination of the supernatant.     -   7. Resuspension in 100 μl of an acetonitrile, demineralised         water and formic acid mixture (50/50/0.1%).     -   8. Filtration with a filter with a porosity of 0.45 μm.     -   9. Injection into a mass spectrometer in single MS mode.     -   10. Acquisition of a mass spectrum.     -   11. Comparing the obtained spectrum with the spectra contained         in a knowledge base.     -   12. Identification of the microorganism by referring to         reference spectra.

EXAMPLE 5 Obtaining Digested Proteins from Microorganisms

The following protocol is conventionally performed in 17 steps:

-   -   1. Sampling of a microorganism colony, obtained according to         Example 1, or of an enriched sample according to Example 2, and         suspension in 10 to 100 μl of a 6M guanidine hydrochloride         solution, 50 mM Tris-HCl, pH=8.0.     -   2. Addition of dithiothreitol (DTT) to achieve an end         concentration of 5 mM.     -   3. Reduction for 20 minutes at 95° C. in a water bath.     -   4. Cooling the tubes to ambient temperature.     -   5. Addition of iodoacetamide to obtain an end concentration of         12.5 mM.     -   6. Alkylation for 40 minutes at ambient temperature and in the         dark.     -   7. Dilution by a factor of 6 with a 50 mM NH₄HCO₃ solution,         pH=8.0 to obtain an end guanidine hydrochloride concentration of         1M.     -   8. Addition of 1 μg of trypsin.     -   9. Digestion at 37° C. for between 6 hours and one night.     -   10. Addition of formic acid down to a pH below 4 to stop the         reaction.     -   11. The sample volume is made up to 1 mL with water/0.5% (v/v)         formic acid     -   12. Balancing of the Waters Oasis HLB columns with 1 ml of         methanol and then 1 ml of H₂O/0.1% (v/v) formic acid     -   13. Deposition of the sample which runs off by gravity     -   14. Washing with 1 ml of H₂O/0.1% (v/v) formic acid     -   15. Elution with 1 ml of a mixture of 80% methanol and 20%         water/0.1% (v/v) formic acid     -   16. The eluate is evaporated with a SpeedVac® SPD2010 evaporator         (Thermo Electron Corporation, Waltham, Mass., United States of         America) over 2 hours, in order to obtain a volume of around 100         μl.     -   17. The eluate is then taken up in a water/0.5% (v/v) formic         acid solution in a quantity sufficient for (QSF) 250 μl

EXAMPLE 6 Identification of a Resistance to NDM-1 Beta-Lactams

Samples Sam1 to Sam9 are identified according to one of the methods described in examples 1, 3 or 4. The identification of the species is set out in TABLE 1.

TABLE 1 Names Species Sam1 K. pneumoniae Sam2 C. freundii Sam3 A. baumannii Sam4 A. caviae Sam5 C. braakii Sam6 E. cloacae Sam7 P. rettgeri Sam8 E. coli Sam9 K. pneumoniae

Samples Sam1 to Sam9 correspond to a species able to comprise an NDM-1 resistance mechanism (Enterobacteriaceae, Pseudomonas species, Acinetobacter species . . . ). The following method is then performed to search for such a mechanism.

Each sample is treated according to Example 5, then a volume of 50 μl of digested proteins is injected and analysed according to the following conditions:

-   -   Dionex Ultimate 3000 chromatographic channel from the Dionex         Corporation (Sunnyvale, United States of America).     -   Waters BEH130 C18 Column, 2.1 mm inner diameter, 100 mm length,         3.5 μm particle size (Waters, Saint-Quentin En Yvelines,         France).     -   Solvent A: H₂O+0.1% formic acid.     -   Solvent B: ACN+0.1% formic acid.

HPLC gradient defined in Table 2 hereafter:

TABLE 2 Time (min) Flow (μl) Solvent A (%) Solvent B (%) 0 300 98 2 3 300 98 2 34 300 54.6 45.4 35 300 0 100 55 300 0 100 55.1 300 98 2 74 300 98 2

-   -   The eluate coming from the chromatographic column is directly         injected into the ionising source of the QTRAP® 5500 mass         spectrometer from Applied Biosystems (Foster City, United States         of America).     -   The peptides coming from the digestion of the microorganism         proteins are analysed by the mass spectrometer in MRM mode. Only         the peptides indicated in TABLE 3 are detected. To this end, the         fragment(s) indicated in TABLE 3 is/are detected.

TABLE 3 Charge state Retention (m/z) (m/z) Collision Transition of the time filtered filtered in energy number Peptide precursor Fragment ion (minutes) in Q1 Q3 (eV) 1 AAITHTAR 2 y4 5.61 420.74 484.26 24 monocharged 2 AAITHTAR 2 y5 5.61 420.74 585.31 24 monocharged 3 AAITHTAR 2 y6 5.61 420.74 698.39 24 monocharged 4 AFGAAFPK 2 y6 16.03 404.72 590.33 23 monocharged 5 AFGAAFPK 2 y7 16.03 404.72 737.4 23 monocharged 6 AFGAAFPK 2 y7 dicharged 16.03 404.72 369.2 23 7 ASMIVMSHSAPDSR 2 y7 13.65 744.85 769.36 38 monocharged 8 ASMIVMSHSAPDSR 2 y8 13.65 744.85 856.39 38 monocharged 9 ASMIVMSHSAPDSR 2 y9 13.65 744.85 987.43 38 monocharged 10 FGDLVFR 2 y4 19.14 427.23 534.34 24 monocharged 11 FGDLVFR 2 y5 19.14 427.23 649.37 24 monocharged 12 FGDLVFR 2 y6 19.14 427.23 706.39 24 monocharged 13 MELPNIMHPVAK 2 y10 dicharged 19.09 690.36 560.32 35 14 MELPNIMHPVAK 2 y9 19.09 690.36 1006.55 35 monocharged 15 MELPNIMHPVAK 2 y9 dicharged 19.09 690.36 503.78 35 16 QEINLPVALAVVTHAHQDK 3 y14 dicharged 21.34 695.05 743.41 39 17 QEINLPVALAVVTHAHQDK 3 y7 21.34 695.05 836.4 39 monocharged 18 QEINLPVALAWTHAHQDK 3 y8 21.34 695.05 935.47 39 monocharged 19 SLGNLGDADTEHYAASAR 2 y14 dicharged 14.64 924.43 738.84 46 20 SLGNLGDADTEHYAASAR 2 y16 dicharged 14.64 924.43 824.37 46 21 SLGNLGDADTEHYAASAR 2 y7 14.64 924.43 775.38 46 monocharged 22 VLVVDTAWTDDQTAQILNWIK 3 y5 27.16 810.43 673.4 45 monocharged 23 VLVVDTAWTDDQTAQILNWIK 3 y6 27.16 810.43 786.49 45 monocharged 24 VLVVDTAWTDDQTAQILNWIK 3 y7 27.16 810.43 914.55 45 monocharged

The precursor peptide charge state, its retention time, the fragment ion type and the transitions, i.e. the (m/z)₁ ratio in Q1 and (m/z)₂ ratio in Q3 are indicated in TABLE 3. The collision energy used to fragment the precursor ion is also indicated in TABLE 3.

-   -   The other machine parameters used are as follows:     -   Scan type: MRM     -   MRM planned: yes     -   Polarity: Positive     -   Ionising source: Turbo V™ (Applied BioSystems)     -   Q1 setting: Filtering with unit resolution     -   Q3 setting: Filtering with unit resolution     -   Inter-scan pause: 5.00 msec     -   Scanning speed: 10 Da/s     -   Curtain gas: 50.00 psi     -   Cone voltage: 5500.00 V     -   Source temperature: 500.00° C.     -   Nebulising gas: 50.00 psi     -   Heating gas: 40.00 psi     -   Collision gas which induces dissociation: 9.00 psi     -   Dynamic filling: activated     -   Declustering potential (DP): 80.00 V     -   Entry potential before Q0 (EP): 10.00 V     -   Collision cell exit potential (CXP): 35 V     -   Total cycle time: 1.2 sec     -   Detection window: 90 sec

The areas obtained for each of the transitions and for each of the microorganisms studied were measured. All the transitions having an area greater than or equal to 2500 (arbitrary unit) are considered to be positive and have been labelled “1” in TABLE 4. All the transitions having an area less than 2500 are considered to be negative and have been labelled 0 in TABLE 4. When no signal peak was observed, the transition has been labelled as negative.

TABLE 4 Tran- sition number Sam1 Sam2 Sam3 Sam4 Sam5 Sam6 Sam7 Sam8 Sam9 1 1 1 1 1 1 1 0 1 1 2 1 1 1 1 1 1 1 1 1 3 1 1 0 1 1 1 0 1 1 4 1 1 1 1 1 1 1 1 1 5 1 1 1 1 1 1 1 1 1 6 1 1 0 1 1 1 1 1 1 7 0 0 0 0 0 0 0 0 0 8 0 0 0 0 0 0 0 0 0 9 0 0 0 0 0 0 0 0 0 10 1 1 1 1 1 1 1 1 1 11 1 1 1 1 1 1 1 1 1 12 1 1 1 1 1 1 1 1 1 13 0 0 0 0 0 0 0 0 0 14 0 0 0 0 0 0 0 0 0 15 0 0 0 0 0 0 0 0 0 16 1 1 0 1 1 0 0 0 1 17 1 1 0 1 1 1 1 0 1 18 1 1 0 1 1 0 1 0 1 19 0 0 0 0 0 0 0 0 0 20 0 0 0 0 0 0 0 0 0 21 0 0 0 0 0 0 0 0 0 22 0 0 0 0 0 0 0 0 0 23 0 0 0 0 0 0 0 0 0 24 0 0 0 0 0 0 0 0 0

The number of positive transitions is then added up and set out in TABLE 5:

TABLE 5 Number of positive Names Species transitions Sam1 K. pneumoniae 12 Sam2 C. freundii 12 Sam3 A. baumannii 7 Sam4 A. caviae 12 Sam5 C. braakii 12 Sam6 E. cloacae 10 Sam7 P. rettgeri 9 Sam8 E. coli 9 Sam9 K. pneumoniae 12

Samples Sam1 to Sam9 comprise more than 6 positive transitions, they therefore contain bacteria which express the NDM-1 protein. The bacteria of Sam1 to Sam9 are therefore resistant to penicillins, to cephalosporins and to carbapenems.

EXAMPLE 7 Identification of a Resistance to KPC Beta-Lactams

Samples Sam62 to Sam73 are identified according to one of the methods described in examples 1, 3 or 4. The identification of the species is set out in TABLE 6.

TABLE 6 Names Species Sam62 K. pneumoniae Sam63 K. pneumoniae Sam64 K. pneumoniae Sam65 K. pneumoniae Sam66 K. pneumoniae Sam67 K. pneumoniae Sam68 K. pneumoniae Sam69 K. pneumoniae Sam70 K. pneumoniae Sam71 K. pneumoniae Sam72 K. pneumoniae Sam73 K. pneumoniae

Samples Sam62 to Sam73 correspond to a species able to comprise a KPC resistance mechanism. The following method is then performed to detect such a mechanism.

Each sample is treated according to Example 5, then analysed according to Example 6 by detecting the peptides from TABLE 7 instead of the peptides from TABLE 3.

TABLE 7 Charge Transition Methionine state of the Clinical number Peptide oxidation precursor Fragment ion interest 1 AAVPADWAVGDK no 2 y9 dicharged 2f 2 AAVPADWAVGDK no 2 y10 dicharged 2f 3 AAVPADWAVGDK no 2 y9 monocharged 2f 4 APIVLAVYTR no 2 y7 monocharged 2f 5 APIVLAVYTR no 2 y5 monocharged 2f 6 APIVLAVYTR no 2 y6 monocharged 2f 7 AVTESLQK no 2 y5 monocharged 2f 8 AVTESLQK no 2 y6 monocharged 2f 9 AVTESLQK no 2 y4 monocharged 2f 10 ELGGPAGLTAFMR yes 2 y7 monocharged 2f 11 ELGGPAGLTAFMR yes 2 y5 monocharged 2f 12 ELGGPAGLTAFMR yes 2 y9 dicharged 2f 13 ELGGPAGLTAFMR no 2 y7 monocharged 2f 14 ELGGPAGLTAFMR no 2 y5 monocharged 2f 15 ELGGPAGLTAFMR no 2 y9 dicharged 2f 16 FPLCSSFK no 2 y6 monocharged 2f 17 FPLCSSFK no 2 y7 monocharged 2f 18 FPLCSSFK no 2 y5 monocharged 2f 19 GFLAAAVLAR no 2 y6 monocharged 2f 20 GFLAAAVLAR no 2 y7 monocharged 2f 21 GFLAAAVLAR no 2 y5 monocharged 2f 22 GNTTGNHR no 2 y5 monocharged 2f 23 GNTTGNHR no 2 y6 monocharged 2f 24 GNTTGNHR no 2 y4 monocharged 2f 25 LALEGLGVNGQ no 3 y8 monocharged 2f 26 LALEGLGVNGQ no 3 y7 monocharged 2f 27 LALEGLGVNGQ no 3 y6 monocharged 2f 28 LTLGSALAAPQR no 3 y9 monocharged 2f 29 LTLGSALAAPQR no 3 y5 monocharged 2f 30 LTLGSALAAPQR no 3 y6 monocharged 2f 31 NALVPWSPISEK no 2 y8 monocharged 2f 32 NALVPWSPISEK no 2 y8 dicharged 2f 33 NALVPWSPISEK no 2 y5 monocharged 2f 34 QQFVDWLK no 2 y5 monocharged 2f 35 QQFVDWLK no 2 y6 monocharged 2f 36 QQFVDWLK no 2 y4 monocharged 2f 37 SIGDTTFR no 2 y5 monocharged 2f 38 SIGDTTFR no 2 y6 monocharged 2f 39 SIGDTTFR no 2 y4 monocharged 2f 40 SQQQAGLLDTPIR no 2 y8 monocharged 2f 41 SQQQAGLLDTPIR no 2 y9 monocharged 2f 42 SQQQAGLLDTPIR no 2 y10 monocharged 2f 43 WELELNSAIPGDAR no 2 y5 monocharged 2f 44 WELELNSAIPGDAR no 2 y8 monocharged 2f 45 WELELNSAIPGDAR no 2 y9 monocharged 2f

The transitions mentioned in TABLE 7 are detected by using the parameters set out in TABLE 8.

Retention (m/z) (m/z) Collision Transition time filtered filtered in energy Positivity number (minutes) in Q1 Q3 (eV) threshold 1 16.29 600.31 479.73 31 2000 2 16.29 600.31 529.27 31 2000 3 16.29 600.31 958.46 31 2000 4 19.07 551.83 821.49 29 13000 5 19.07 551.83 609.33 29 13000 6 19.07 551.83 722.42 29 13000 7 10.38 438.25 604.33 24 2000 8 10.38 438.25 705.38 24 2000 9 10.38 438.25 475.29 24 2000 10 18.55 668.34 811.41 34 2000 11 18.55 668.34 641.31 34 2000 12 18.55 668.34 490.26 34 2000 13 21.72 660.34 795.42 34 2000 14 21.72 660.34 625.31 34 2000 15 21.72 660.34 482.26 34 2000 16 17.56 493.24 741.36 27 2000 17 17.56 493.24 838.41 27 2000 18 17.56 493.24 628.28 27 2000 19 20.67 494.8 600.38 27 14000 20 20.67 494.8 671.42 27 14000 21 20.67 494.8 529.35 27 14000 22 1.19 428.7 584.29 24 2000 23 1.19 428.7 685.34 24 2000 24 1.19 428.7 483.24 24 2000 25 18.89 535.8 773.38 42 2000 26 18.89 535.8 644.34 42 2000 27 18.89 535.8 587.31 42 2000 28 17.37 599.35 870.48 42 2000 29 17.37 599.35 542.3 42 2000 30 17.37 599.35 655.39 42 2000 31 20 670.86 943.49 35 2000 32 20 670.86 472.25 35 2000 33 20 670.86 573.32 35 2000 34 20.48 532.28 660.37 28 2000 35 20.48 532.28 807.44 28 2000 36 20.48 532.28 561.3 28 2000 37 13.42 448.73 639.31 25 2000 38 13.42 448.73 696.33 25 2000 39 13.42 448.73 524.28 25 2000 40 17.6 713.89 884.52 36 2000 41 17.6 713.89 955.56 36 2000 42 17.6 713.89 1083.62 36 2000 43 21.1 785.9 515.26 40 2000 44 21.1 785.9 786.41 40 2000 45 21.1 785.9 900.45 40 2000

The areas obtained for each of the transitions and for each of the microorganisms studied were measured. When the areas of the 3 transitions of the same peptide are greater than or equal to the positivity threshold described in TABLE 8, the detection of the peptide is considered to be positive and is labelled “1” in TABLE 9. When at least one transition comprises an area less than the positivity threshold described in TABLE 8, the corresponding peptide is considered non-detected and is labelled “0” in TABLE 9.

TABLE 9 Transition number Sam62 Sam63 Sam64 Sam65 Sam66 Sam67 Sam68 Sam69 Sam70 Sam71 Sam72 Sam73 1 0 0 0 0 0 0 1 1 1 1 1 1 2 0 0 0 0 0 0 1 1 1 1 1 1 3 0 0 0 0 0 0 1 1 1 1 1 1 4 0 0 0 0 0 0 1 1 1 1 1 1 5 0 0 0 0 0 0 1 1 1 1 1 1 6 0 0 0 0 0 0 1 1 1 1 1 1 7 0 0 0 0 0 0 0 0 0 0 0 0 8 0 0 0 0 0 0 0 0 0 0 0 0 9 0 0 0 0 0 0 0 0 0 0 0 0 10 0 0 0 0 0 0 0 0 0 0 0 0 11 0 0 0 0 0 0 0 0 0 0 0 0 12 0 0 0 0 0 0 0 0 0 0 0 0 13 0 0 0 0 0 0 1 1 1 1 1 1 14 0 0 0 0 0 0 1 1 1 1 1 1 15 0 0 0 0 0 0 1 1 1 1 1 1 16 0 0 0 0 0 0 0 0 0 0 0 0 17 0 0 0 0 0 0 0 0 0 0 0 0 18 0 0 0 0 0 0 0 0 0 0 0 0 19 0 0 0 0 0 0 1 1 1 1 1 1 20 0 0 0 0 0 0 1 1 1 1 1 1 21 0 0 0 0 0 0 1 1 1 1 1 1 22 0 0 0 0 0 0 0 0 0 0 0 0 23 0 0 0 0 0 0 0 0 0 0 0 0 24 0 0 0 0 0 0 0 0 0 0 0 0 25 0 0 0 0 0 0 0 0 0 0 0 0 26 0 0 0 0 0 0 0 0 0 0 0 0 27 0 0 0 0 0 0 0 0 0 0 0 0 28 0 0 0 0 0 0 1 1 1 1 1 1 29 0 0 0 0 0 0 1 1 1 1 1 1 30 0 0 0 0 0 0 1 1 1 1 1 1 31 0 0 0 0 0 0 1 1 1 1 1 1 32 0 0 0 0 0 0 1 1 1 1 1 1 33 0 0 0 0 0 0 1 1 1 1 1 1 34 0 0 0 0 0 0 0 0 0 0 0 0 35 0 0 0 0 0 0 0 0 0 0 0 0 36 0 0 0 0 0 0 0 0 0 0 0 0 37 0 0 0 0 0 0 1 1 1 1 1 1 38 0 0 0 0 0 0 1 1 1 1 1 1 39 0 0 0 0 0 0 0 0 0 0 0 0 40 0 0 0 0 0 0 1 1 1 1 1 1 41 0 0 0 0 0 0 1 1 1 1 1 1 42 0 0 0 0 0 0 1 1 1 1 1 1 43 0 0 0 0 0 0 0 0 0 0 0 0 44 0 0 0 0 0 0 0 0 0 0 0 0 45 0 0 0 0 0 0 0 0 0 0 0 0 Sum of the 0 0 0 0 0 0 23 23 23 23 23 23 transitions

Samples Sam68 to Sam73 comprise at least one transition which is characteristic of KPCs. The bacteria present in samples Sam68 to Sam73 therefore express a beta-lactamase which confers on them a resistance to penicillins, to cephalosporins, including third-generation cephalosporins such as cefotaxime/ceftazidime, to monobactams and to carbapenems.

Samples Sam62 to Sam67 comprise no transition which is characteristic of KPCs. The bacteria present in samples Sam62 to Sam67 therefore do not express KPC beta-lactamase and may be sensitive to carbapenem antibiotics.

EXAMPLE 8 Identification of a Resistance to NDM-1 or KPC Beta-Lactams

The samples corresponding to a species able to comprise an NDM-1 or KPC resistance mechanism can be detected by employing the following method.

Each sample is treated according to Example 5, then analysed according to Example 6 by detecting the peptides from TABLE 10 instead of the peptides from TABLE 3.

TABLE 10 Transition First-generation Charge state of Clinical Proteins number Peptide fragment ion the precursor interest NDM-1 1 AAITHTAR y4 monocharged 2 3a NDM-1 2 AAITHTAR y5 monocharged 2 3a NDM-1 3 AAITHTAR y6 monocharged 2 3a NDM-1 4 AFGAAFPK y6 monocharged 2 3a NDM-1 5 AFGAAFPK y7 monocharged 2 3a NDM-1 6 AFGAAFPK y7 dicharged 2 3a NDM-1 7 FGDLVFR y4 monocharged 2 3a NDM-1 8 FGDLVFR y5 monocharged 2 3a NDM-1 9 FGDLVFR y6 monocharged 2 3a NDM-1 10 QEINLPVALAVVTHAHQDK y14 dicharged 3 3a NDM-1 11 QEINLPVALAVVTHAHQDK y7 monocharged 3 3a NDM-1 12 QEINLPVALAVVTHAHQDK y8 monocharged 3 3a KPC 13 AAVPADWAVGDK y9 dicharged 2 2f KPC 14 AAVPADWAVGDK y10 dicharged 2 2f KPC 15 AAVPADWAVGDK y9 monocharged 2 2f KPC 16 APIVLAVYTR y7 monocharged 2 2f KPC 17 APIVLAVYTR y5 monocharged 2 2f KPC 18 APIVLAVYTR y6 monocharged 2 2f KPC 19 ELGGPAGLTAFMR y7 monocharged 2 2f KPC 20 ELGGPAGLTAFMR y5 monocharged 2 2f KPC 21 ELGGPAGLTAFMR y9 dicharged 2 2f KPC 22 GFLAAAVLAR y6 monocharged 2 2f KPC 23 GFLAAAVLAR y7 monocharged 2 2f KPC 24 GFLAAAVLAR y5 monocharged 2 2f KPC 25 LTLGSALAAPQR y9 monocharged 3 2f KPC 26 LTLGSALAAPQR y5 monocharged 3 2f KPC 27 LTLGSALAAPQR y6 monocharged 3 2f KPC 28 NALVPWSPISEK y8 monocharged 2 2f KPC 29 NALVPWSPISEK y8 dicharged 2 2f KPC 30 NALVPWSPISEK y5 monocharged 2 2f KPC 31 SQQQAGLLDTPIR y8 monocharged 2 2f KPC 32 SQQQAGLLDTPIR y9 monocharged 2 2f KPC 33 SQQQAGLLDTPIR y10 monocharged 2 2f

The entry 2f indicates the presence of a carbapenemase beta-lactamase from subgroup 2f according to the Bush and Jacoby classification [Antimicrob Agents Chemother. 2010 March; 54(3):969-76. Epub 2009 Dec. 7. Updated functional classification of beta-lactamases], capable of hydrolysing carbapenems.

The entry 3a indicates the presence of a metallo-beta-lactamase from subgroup 3a according to the Bush and Jacoby classification [9], supra, capable of hydrolysing penicillins, cephalosporins and carbapenems.

The transitions mentioned in TABLE 10 are detected by using the parameters set out in TABLE 11.

TABLE 11 Retention (m/z) (m/z) Collision Transition time filtered in filtered in energy Positivity number (minutes) Q1 Q3 (eV) threshold 1 5.61 420.74 484.26 24 2500 2 5.61 420.74 585.31 24 2500 3 5.61 420.74 698.39 24 2500 4 16.03 404.72 590.33 23 2500 5 16.03 404.72 737.4 23 2500 6 16.03 404.72 369.2 23 2500 7 19.14 427.23 534.34 24 2500 8 19.14 427.23 649.37 24 2500 9 19.14 427.23 706.39 24 2500 10 21.34 695.05 743.41 39 2500 11 21.34 695.05 836.4 39 2500 12 21.34 695.05 935.47 39 2500 13 16.29 600.31 479.73 31 2000 14 16.29 600.31 529.27 31 2000 15 16.29 600.31 958.46 31 2000 16 19.07 551.83 821.49 29 13000 17 19.07 551.83 609.33 29 13000 18 19.07 551.83 722.42 29 13000 19 21.72 660.34 795.42 34 2000 20 21.72 660.34 625.31 34 2000 21 21.72 660.34 482.26 34 2000 22 20.67 494.8 600.38 27 14000 23 20.67 494.8 671.42 27 14000 24 20.67 494.8 529.35 27 14000 25 17.37 599.35 870.48 42 2000 26 17.37 599.35 542.3 42 2000 27 17.37 599.35 655.39 42 2000 28 20 670.86 943.49 35 2000 29 20 670.86 472.25 35 2000 30 20 670.86 573.32 35 2000 31 17.6 713.89 884.52 36 2000 32 17.6 713.89 955.56 36 2000 33 17.6 713.89 1083.62 36 2000

When the areas of at least two transitions of the same peptide are greater than or equal to the positivity threshold described in TABLE 11, the detection of the peptide is considered to be positive. When more than two transitions of the same peptide comprise an area less than the positivity threshold described in TABLE 11, the corresponding peptide is considered non-detected.

A sample contains bacteria which express the NDM-1 protein, when at least one peptide corresponding to the NDM-1 resistance mechanism is detected. These bacteria are resistant to penicillins, to cephalosporins and to carbapenems.

A sample contains bacteria which express the KPC protein, when at least one peptide corresponding to the KPC resistance mechanism is detected. These bacteria are resistant to penicillins, to cephalosporins, including third-generation cephalosporins such as cefotaxime/ceftazidime, to monobactams and to carbapenems.

EXAMPLE 9 Identification of a Resistance to IND Beta-Lactams

Samples Sam84 to Sam88 are identified according to one of the methods described in examples 1, 3 or 4. The identification of the species is set out in TABLE 12.

TABLE 12 Names Species Sam84 C. indologenes Sam85 C. indologenes Sam86 C. indologenes Sam87 C. indologenes Sam88 C. indologenes

Samples Sam84 to Sam88 correspond to a species able to comprise an IND resistance mechanism. The following method is then performed to detect such a mechanism.

Each sample is treated according to Example 5, then analysed according to Example 6 unless otherwise stated in the rest of the example, by detecting the peptides from TABLE 13 instead of the peptides from TABLE 3.

TABLE 13 Collision Retention (m/z) (m/z) Declustering Collision cell exit Transition time filtered filtered potential energy potential Positivity number Peptide (minutes) in Q1 in Q3 (eV) (eV) (eV) threshold 1 AATDLGYIK 14.66 476.26 593.37 65.8 26 15 2000 2 AATDLGYIK 14.66 476.26 708.39 65.8 26 15 2000 3 AATDLGYIK 14.66 476.26 809.44 65.8 26 15 2000 4 AGDLSFFNNK 18.08 556.77 522.27 71.7 29.5 15 2000 5 AGDLSFFNNK 18.08 556.77 669.34 71.7 29.5 15 2000 6 AGDLSFFNNK 18.08 556.77 756.37 71.7 29.5 15 2000 7 AGDLSFYNK 14.82 507.75 424.22 68.1 27.3 15 2000 8 AGDLSFYNK 14.84 507.75 571.29 68.1 27.3 15 2000 9 AGDLSFYNK 14.84 507.75 658.32 68.1 27.3 15 2000 10 AGDLSFYNQK 14.91 571.78 552.28 72.8 30.2 15 2000 11 AGDLSFYNQK 14.93 571.78 699.35 72.8 30.2 15 2000 12 AGDLSFYNQK 14.93 571.78 786.38 72.8 30.2 15 2000 13 AQYQSLMDTIK 18.01 649.33 1098.55 78.5 33.6 15 2000 14 AQYQSLMDTIK 18.01 649.33 607.31 78.5 33.6 15 2000 15 AQYQSLMDTIK 18.01 649.33 807.43 78.5 33.6 15 2000 16 ASLVIPGHDEWK 16.84 676.35 434.70 80.4 34.8 15 2000 17 ASLVIPGHDEWK 16.8 676.35 868.40 80.4 34.8 15 2000 18 ASLVIPGHDEWK 16.82 676.35 981.48 80.4 34.8 15 2000 19 ATLIIPGHDDWK 17.47 683.36 427.69 80.9 35.1 15 2000 20 ATLIIPGHDDWK 17.47 683.36 854.38 80.9 35.1 15 2000 21 ATLIIPGHDDWK 17.47 683.36 967.46 80.9 35.1 15 2000 22 ATLIIPGHDEWK 17.54 690.37 1094.56 81.4 35.4 10 2000 23 ATLIIPGHDEWK 17.54 690.37 868.40 81.4 35.4 10 2000 24 ATLIIPGHDEWK 17.54 690.37 981.48 81.4 35.4 10 2000 25 ATSTELIKPGK 11.63 572.83 301.19 72.9 30.2 15 2000 26 ATSTELIKPGK 11.67 572.83 486.79 72.9 30.2 15 2000 27 ATSTELIKPGK 11.67 572.83 655.45 72.9 30.2 15 2000 28 DFVIEPPIK 19.93 529.30 454.30 69.7 28.3 15 2000 29 DFVIEPPIK 19.93 529.30 696.43 69.7 28.3 15 2000 30 DFVIEPPIK 19.93 529.30 795.50 69.7 28.3 15 2000 31 DFVIEPPVKPNLYLYK 22.03 645.69 730.91 78.2 36.3 15 2000 32 DFVIEPPVKPNLYLYK 22.03 645.69 787.45 78.2 36.3 15 2000 33 DFVIEPPVKPNLYLYK 22.08 645.69 836.99 78.2 36.3 15 2000 34 DFVIEQPFGK 19.77 590.31 448.26 74.2 31 15 2000 35 DFVIEQPFGK 19.75 590.31 705.36 74.2 31 15 2000 36 DFVIEQPFGK 19.75 590.31 818.44 74.2 31 15 2000 37 EANLEQWPK 15.53 557.78 430.25 71.8 29.5 15 2000 38 EANLEQWPK 15.55 557.78 558.30 71.8 29.5 15 2000 39 EANLEQWPK 15.55 557.78 687.35 71.8 29.5 15 2000 40 EANVEQWPITIDK 19.5 514.93 343.71 68.7 29.7 10 2000 41 EANVEQWPITIDK 19.5 514.93 686.41 68.7 29.7 10 2000 42 EANVEQWPITIDK 19.48 514.93 872.49 68.7 29.7 10 2000 43 EANVEQWPK 13.84 550.77 430.25 71.3 29.2 15 2000 44 EANVEQWPK 13.86 550.77 558.30 71.3 29.2 15 2000 45 EANVEQWPK 13.86 550.77 687.35 71.3 29.2 15 2000 46 EQYQTLMDTIQK 17.9 749.37 735.37 85.7 38 10 2000 47 EQYQTLMDTIQK 17.9 749.37 848.46 85.7 38 10 2000 48 EQYQTLMDTIQK 17.9 749.37 949.50 85.7 38 10 2000 49 EYSANAVYLTTK 15.26 680.34 1067.57 80.7 34.9 10 2000 50 EYSANAVYLTTK 15.28 680.34 625.36 80.7 34.9 10 2000 51 EYSANAVYLTTK 15.26 680.34 795.46 80.7 34.9 10 2000 52 EYSANSMYLVTK 16.5 703.34 1113.56 82.4 35.9 10 2000 53 EYSANSMYLVTK 16.5 703.34 841.45 82.4 35.9 10 2000 54 EYSANSMYLVTK 16.5 703.34 955.49 82.4 35.9 10 2000 55 EYSANSVYLVTK 16.19 687.35 1081.59 81.2 35.2 10 2000 56 EYSANSVYLVTK 16.14 687.35 623.38 81.2 35.2 10 2000 57 EYSANSVYLVTK 16.12 687.35 923.52 81.2 35.2 10 2000 58 EYSANSVYLVTQK 16.19 501.26 376.22 67.7 29.1 10 2000 59 EYSANSVYLVTQK 16.19 501.26 475.29 67.7 29.1 10 2000 60 EYSANSVYLVTQK 16.21 501.26 751.44 67.7 29.1 10 2000 61 EYSTNALYLVTK 18.83 701.37 1109.62 82.2 35.9 10 2000 62 EYSTNALYLVTK 18.83 701.37 460.31 82.2 35.9 10 2000 63 EYSTNALYLVTK 18.81 701.37 623.38 82.2 35.9 10 2000 64 GGGHVEHTLELLDK 15.6 502.26 730.44 67.7 29.1 10 2000 65 GGGHVEHTLELLDK 15.6 502.26 831.48 67.7 29.1 10 2000 66 GGGHVEHTLELLDK 15.6 502.26 968.54 67.7 29.1 10 2000 67 GGGHVEHTLELLNK 15 501.94 616.37 67.7 29.1 10 2000 68 GGGHVEHTLELLNK 15 501.94 729.45 67.7 29.1 10 2000 69 GGGHVEHTLELLNK 15 501.94 830.50 67.7 29.1 10 2000 70 GGGHVQHTLDLLDK 15.35 745.39 1082.58 85.5 37.8 10 2000 71 GGGHVQHTLDLLDK 15.35 745.39 1181.65 85.5 37.8 10 2000 72 GGGHVQHTLDLLDK 15.35 745.39 488.31 85.5 37.8 10 2000 73 GIPTYATAK 12.63 461.26 376.20 64.7 25.3 15 2000 74 GIPTYATAK 12.63 461.26 654.35 64.7 25.3 15 2000 75 GIPTYATAK 12.63 461.26 751.40 64.7 25.3 15 2000 76 GNDHVK 1.3 335.17 383.24 55.6 19.7 15 2000 77 GNDHVK 1.3 335.17 498.27 55.6 19.7 15 2000 78 GNDHVK 1.3 335.17 612.31 55.6 19.7 15 2000 79 GVVLFDVPWEK 23.79 644.86 559.29 78.1 33.4 15 2000 80 GVVLFDVPWEK 23.82 644.86 658.36 78.1 33.4 15 2000 81 GVVLFDVPWEK 23.82 644.86 920.45 78.1 33.4 15 2000 82 GVVLFDVPWQK 23.32 644.36 558.30 78.1 33.4 15 2000 83 GVVLFDVPWQK 23.32 644.36 772.40 78.1 33.4 15 2000 84 GVVLFDVPWQK 23.32 644.36 919.47 78.1 33.4 15 2000 85 HNLPVIAVFATHSHSDR 17.94 634.33 768.90 77.4 35.7 15 2000 86 HNLPVIAVFATHSHSDR 17.95 634.33 825.44 77.4 35.7 15 2000 87 HNLPVIAVFATHSHSDR 17.93 634.33 882.46 77.4 35.7 15 2000 88 HNLPVVAVFATHSHDDR 17.17 638.99 775.89 77.7 35.9 15 2000 89 HNLPVVAVFATHSHDDR 17.17 638.99 832.43 77.7 35.9 15 2000 90 HNLPVVAVFATHSHDDR 17.17 638.99 889.45 77.7 35.9 15 2000 91 HTLELLDQQK 15.02 612.83 403.23 75.8 32 15 2000 92 HTLELLDQQK 15.02 612.83 518.26 75.8 32 15 2000 93 HTLELLDQQK 15.02 612.83 986.55 75.8 32 15 2000 94 HTLELLNK 14.44 484.28 616.37 66.4 26.3 15 2000 95 HTLELLNK 14.44 484.28 729.45 66.4 26.3 15 2000 96 HTLELLNK 14.44 484.28 830.50 66.4 26.3 15 2000 97 IQYQSLMDTIK 19.41 670.34 1098.55 80 34.5 15 2000 98 IQYQSLMDTIK 19.38 670.34 607.31 80 34.5 15 2000 99 IQYQSLMDTIK 19.41 670.34 807.43 80 34.5 15 2000 100 NLHIYK 11.54 394.23 337.21 59.9 22.3 15 2000 101 NLHIYK 11.54 394.23 423.26 59.9 22.3 15 2000 102 NLHIYK 11.54 394.23 560.32 59.9 22.3 15 2000 103 NLYIYK 14.93 407.23 423.26 60.8 22.9 15 2000 104 NLYIYK 14.91 407.23 586.32 60.8 22.9 15 2000 105 NLYIYK 14.93 407.23 699.41 60.8 22.9 15 2000 106 NNLHIYK 11.29 451.25 423.26 64 24.9 15 2000 107 NNLHIYK 11.29 451.25 560.32 64 24.9 15 2000 108 NNLHIYK 11.27 451.25 673.40 64 24.9 15 2000 109 QLYLYK 15.22 414.24 423.26 61.3 23.2 15 2000 110 QLYLYK 15.2 414.24 586.32 61.3 23.2 15 2000 111 QLYLYK 15.22 414.24 699.41 61.3 23.2 15 2000 112 QWPETMR 14.84 474.22 317.16 65.7 25.9 15 2000 113 QWPETMR 14.75 474.22 407.21 65.7 25.9 15 2000 114 QWPETMR 14.73 474.22 633.30 65.7 25.9 15 2000 115 SFGVFGGK 16.69 399.71 356.20 60.3 22.6 15 2000 116 SFGVFGGK 16.69 399.71 408.22 60.3 22.6 15 2000 117 SFGVFGGK 16.69 399.71 564.31 60.3 22.6 15 2000 118 SIQLLMMSMFLSPLINAQVK 32.4 755.41 441.77 86.2 41.8 15 2000 119 SIQLLMMSMFLSPLINAQVK 32.4 755.41 882.54 86.2 41.8 15 2000 120 SIQLLMMSMFLSPLINAQVK 32.4 755.41 969.57 86.2 41.8 15 2000 121 SNSATDLGYIK 14.71 584.80 593.37 73.7 30.7 15 2000 122 SNSATDLGYIK 14.71 584.80 809.44 73.7 30.7 15 2000 123 SNSATDLGYIK 14.71 584.80 967.51 73.7 30.7 15 2000 124 TATDLGYTGEANVK 13.61 720.35 718.37 83.6 36.7 10 2000 125 TATDLGYTGEANVK 13.61 720.35 881.44 83.6 36.7 10 2000 126 TATDLGYTGEANVK 13.61 720.35 938.46 83.6 36.7 10 2000 127 TFGVFDGK 16.56 435.72 466.23 62.9 24.2 15 2000 128 TFGVFDGK 16.58 435.72 622.32 62.9 24.2 15 2000 129 TFGVFDGK 16.58 435.72 769.39 62.9 24.2 15 2000 130 TFGVFGGK 16.78 406.72 408.22 60.8 22.9 15 2000 131 TFGVFGGK 16.76 406.72 564.31 60.8 22.9 15 2000 132 TFGVFGGK 16.78 406.72 711.38 60.8 22.9 15 2000 133 TGKPYK 1.41 347.20 407.23 56.4 20.3 15 2000 134 TGKPYK 1.41 347.20 535.32 56.4 20.3 15 2000 135 TGKPYK 1.41 347.20 592.35 56.4 20.3 15 2000 136 TGKPYR 1.41 361.20 435.24 57.4 20.9 15 2000 137 TGKPYR 1.41 361.20 563.33 57.4 20.9 15 2000 138 TGKPYR 1.41 361.20 620.35 57.4 20.9 15 2000 139 TGVVLFDVPWEK 24.03 695.37 1033.54 81.8 35.6 10 2000 140 TGVVLFDVPWEK 23.97 695.37 559.29 81.8 35.6 10 2000 141 TGVVLFDVPWEK 23.97 695.37 920.45 81.8 35.6 10 2000 142 TNEFLK 12.85 376.20 407.27 58.5 21.6 15 2000 143 TNEFLK 12.88 376.20 536.31 58.5 21.6 15 2000 144 TNEFLK 12.85 376.20 650.35 58.5 21.6 15 2000 145 TNELLK 11.69 359.21 373.28 57.3 20.8 15 2000 146 TNELLK 11.72 359.21 502.32 57.3 20.8 15 2000 147 TNELLK 11.69 359.21 616.37 57.3 20.8 15 2000 148 TNQFLK 12.3 375.71 407.27 58.5 21.5 15 2000 149 TNQFLK 12.27 375.71 535.32 58.5 21.5 15 2000 150 TNQFLK 12.27 375.71 649.37 58.5 21.5 15 2000 151 TQYQSLMDTIK 18.12 664.33 1098.55 79.5 34.2 15 2000 152 TQYQSLMDTIK 18.1 664.33 607.31 79.5 34.2 15 2000 153 TQYQSLMDTIK 18.12 664.33 807.43 79.5 34.2 15 2000 154 TYATAK 1.9 327.68 319.20 55 19.4 15 2000 155 TYATAK 1.85 327.68 390.24 55 19.4 15 2000 156 TYATAK 1.9 327.68 553.30 55 19.4 15 2000 157 TYATPK 7.79 340.68 345.21 56 20 15 2000 158 TYATPK 7.77 340.68 416.25 56 20 15 2000 159 TYATPK 7.79 340.68 579.31 56 20 15 2000 160 TYATSK 1.45 335.67 335.19 55.6 19.8 15 2000 161 TYATSK 1.45 335.67 406.23 55.6 19.8 15 2000 162 TYATSK 1.47 335.67 569.29 55.6 19.8 15 2000 163 VIPGHDEWK 12.43 540.78 434.70 70.5 28.8 15 2000 164 VIPGHDEWK 12.45 540.78 771.34 70.5 28.8 15 2000 165 VIPGHDEWK 12.43 540.78 868.40 70.5 28.8 15 2000 166 VLDGGCLVK 14.44 480.76 633.34 66.2 26.2 15 2000 167 VLDGGCLVK 14.44 480.76 748.37 66.2 26.2 15 2000 168 VLDGGCLVK 14.46 480.76 861.45 66.2 26.2 15 2000 169 VQYQSLMDTIQK 18.24 727.37 1063.55 84.1 37 10 2000 170 VQYQSLMDTIQK 18.24 727.37 1226.61 84.1 37 10 2000 171 VQYQSLMDTIQK 18.24 727.37 935.49 84.1 37 10 2000 172 YAQATLVIPGHDEWK 18.03 576.63 577.26 73.2 32.8 10 2000 173 YAQATLVIPGHDEWK 18.03 576.63 747.39 73.2 32.8 10 2000 174 YAQATLVIPGHDEWK 18.05 576.63 868.40 73.2 32.8 10 2000 175 YAQATLVIPGHEEWK 17.99 581.30 690.37 73.5 33.1 10 2000 176 YAQATLVIPGHEEWK 17.95 581.30 754.40 73.5 33.1 10 2000 177 YAQATLVIPGHEEWK 17.97 581.30 882.41 73.5 33.1 10 2000 178 YNVLDGGCLVK 17.86 619.32 633.34 76.3 32.2 15 2000 179 YNVLDGGCLVK 17.86 619.32 748.37 76.3 32.2 15 2000 180 YNVLDGGCLVK 17.86 619.32 861.45 76.3 32.2 15 2000 181 YPSTAK 4.3 333.68 319.20 55.4 19.7 15 2000 182 YPSTAK 4.44 333.68 406.23 55.4 19.7 15 2000 183 YPSTAK 4.28 333.68 503.28 55.4 19.7 15 2000 184 YSEAVLIIPGHDEWK 19.76 586.30 753.90 73.9 33.3 15 2000 185 YSEAVLIIPGHDEWK 19.72 586.30 797.42 73.9 33.3 15 2000 186 YSEAVLIIPGHDEWK 19.72 586.30 868.40 73.9 33.3 15 2000

-   -   The other machine parameters used are as follows:     -   Scan type: MRM     -   MRM planned: no     -   Polarity: Positive     -   Ionising source: Turbo V™ (Applied BioSystems)     -   Q1 setting: Filtering with unit resolution     -   Q3 setting: Filtering with unit resolution     -   Inter-scan pause: 5.00 msec     -   Scanning speed: 10 Da/s     -   Curtain gas: 40.00 psi     -   Cone voltage: 5500.00 V     -   Source temperature: 500.00° C.     -   Nebulising gas: 50.00 psi     -   Heating gas: 50.00 psi     -   Collision gas which induces dissociation: 9.00 psi     -   Dynamic filling: activated     -   Entry potential before Q0 (EP): 10.00 V

The areas obtained for each of the transitions and for each of the microorganisms studied were measured. When the areas of the transitions are greater than or equal to the positivity threshold described in TABLE 13, the detection of the transition is considered to be positive and is labelled “1” in TABLE 14. When a transition has an area less than the positivity threshold described in TABLE 13, the transition is considered non-detected and is labelled “0” in TABLE 14.

For a given peptide, when at least 3 transitions are labelled “1”, the peptide is considered as being detected.

TABLE 14 Transition number Sam84 Sam85 Sam86 Sam87 Sam88 1 0 1 1 1 1 2 0 0 1 1 0 3 0 0 0 1 0 4 0 0 0 0 0 5 0 0 0 0 0 6 0 0 0 0 0 7 0 0 0 0 0 8 0 0 0 1 0 9 0 0 0 0 0 10 0 1 1 0 1 11 0 0 0 0 0 12 0 0 1 0 0 13 0 0 0 0 0 14 0 0 0 0 0 15 0 0 0 0 0 16 0 0 0 1 0 17 0 0 0 1 0 18 0 1 0 1 1 19 0 0 0 0 0 20 0 0 0 0 0 21 1 1 1 1 0 22 0 0 0 0 0 23 0 0 0 0 0 24 0 0 0 0 0 25 1 1 1 1 1 26 1 1 0 1 1 27 1 1 0 1 1 28 0 1 0 1 1 29 0 1 0 1 1 30 0 1 0 1 1 31 0 0 0 0 0 32 0 0 0 0 0 33 0 0 0 0 0 34 0 0 0 0 0 35 0 0 0 0 0 36 0 0 0 0 0 37 0 0 0 0 0 38 0 0 0 0 0 39 0 0 0 0 0 40 0 0 0 0 0 41 0 0 0 0 0 42 0 0 0 0 0 43 0 0 0 0 0 44 0 0 0 0 0 45 0 0 0 0 0 46 0 0 0 0 0 47 0 0 0 0 0 48 0 0 0 0 0 49 0 0 0 0 0 50 0 0 0 0 0 51 0 0 0 0 0 52 0 0 0 1 0 53 0 0 0 1 0 54 0 0 0 1 0 55 0 0 0 0 0 56 0 0 0 0 0 57 0 0 0 0 0 58 0 0 0 0 0 59 0 0 0 0 0 60 0 0 0 0 0 61 0 0 0 0 0 62 0 0 0 0 0 63 0 0 0 0 0 64 0 0 0 0 0 65 0 0 0 0 0 66 0 0 0 0 0 67 0 0 0 0 0 68 0 0 0 0 0 69 0 0 0 0 0 70 0 0 0 0 0 71 0 0 0 0 0 72 0 0 0 0 0 73 0 0 0 0 0 74 1 0 0 0 0 75 0 0 0 0 0 76 0 0 0 0 0 77 0 0 0 0 0 78 1 0 0 0 0 79 0 0 0 0 0 80 0 0 0 0 0 81 0 0 0 0 0 82 1 0 0 1 0 83 0 0 0 0 0 84 0 0 0 0 0 85 0 0 0 0 0 86 0 0 0 0 0 87 0 0 0 0 0 88 0 0 0 0 0 89 0 0 0 0 0 90 0 0 0 0 0 91 0 0 0 0 0 92 0 0 0 0 0 93 0 0 0 0 0 94 0 0 0 0 0 95 0 0 0 0 0 96 0 0 0 0 0 97 0 0 0 0 0 98 0 0 0 0 0 99 0 0 0 0 0 100 0 0 0 0 0 101 0 0 0 0 0 102 0 0 0 0 0 103 0 0 0 0 0 104 0 0 0 0 0 105 0 0 0 0 0 106 0 0 0 0 0 107 0 0 0 0 0 108 0 0 0 0 0 109 0 0 0 0 0 110 0 0 0 0 0 111 0 0 0 0 0 112 0 0 0 0 0 113 0 0 0 0 0 114 0 0 0 0 0 115 0 0 0 0 0 116 0 0 0 0 0 117 0 0 0 0 0 118 0 0 0 0 0 119 0 0 0 0 0 120 0 0 0 0 0 121 0 0 0 0 0 122 0 0 0 0 0 123 0 0 0 0 0 124 0 0 0 0 0 125 0 0 0 0 0 126 0 0 0 0 0 127 0 0 0 0 0 128 0 0 0 0 0 129 0 0 0 0 0 130 0 0 0 0 0 131 0 0 0 0 0 132 0 0 0 0 0 133 0 1 0 0 1 134 0 1 0 0 1 135 0 1 0 0 1 136 1 0 0 0 0 137 1 0 0 1 0 138 1 0 0 0 1 139 0 0 0 0 0 140 0 0 0 0 0 141 0 0 0 0 0 142 0 0 0 0 0 143 0 0 0 0 0 144 0 0 0 0 0 145 1 0 0 0 0 146 1 0 0 1 0 147 1 0 0 0 0 148 0 0 0 0 0 149 0 0 0 0 0 150 0 0 0 0 0 151 0 0 0 0 0 152 0 0 0 0 0 153 0 0 0 0 0 154 0 0 0 0 0 155 0 0 0 0 0 156 0 0 0 0 0 157 0 0 0 0 0 158 0 0 0 0 0 159 0 0 0 0 0 160 0 0 0 0 0 161 0 0 0 0 0 162 0 0 0 0 0 163 0 0 0 0 0 164 0 0 0 0 0 165 0 0 0 0 0 166 0 0 0 0 0 167 0 0 0 0 0 168 0 0 0 0 0 169 0 0 0 0 0 170 0 0 0 0 0 171 0 0 0 0 0 172 0 0 0 0 0 173 0 0 0 0 0 174 0 0 0 0 0 175 0 1 0 1 1 176 0 1 0 1 1 177 1 1 0 1 1 178 0 0 0 0 0 179 0 0 0 0 0 180 0 0 0 0 0 181 0 0 0 0 0 182 0 0 0 0 0 183 0 0 0 0 0 184 0 0 0 0 0 185 0 0 0 0 0 186 0 0 0 0 0 187 0 0 0 1 0 188 0 0 0 1 0 189 0 1 0 1 0 190 0 0 0 0 0 191 0 0 0 0 0 192 0 0 0 0 0 193 0 0 0 0 0 194 0 0 0 0 0 195 0 0 0 0 0

Samples Sam84 to Sam88 comprise at least one peptide which is characteristic of INDs. The bacteria present in samples Sam84 to Sam88 therefore express a beta-lactamase which confers on them a resistance to penicillins, to cephalosporins and to carbapenems.

EXAMPLE 10 Identification of a Resistance to GES Beta-Lactams

Samples Sam89 and Sam90 are identified according to one of the methods described in examples 1, 3 or 4. The identification of the species is set out in TABLE 15.

TABLE 15 Names Species Sam89 E. coli Sam90 P. aeruginosa

Samples Sam89 and Sam90 correspond to a species able to comprise a GES resistance mechanism. The following method is then performed to detect such a mechanism.

Each sample is treated according to Example 5, then analysed according to Example 6 unless otherwise stated in the rest of the example, by detecting the peptides from TABLE 16 instead of the peptides from TABLE 3.

TABLE 16 Decluste Retention (m/z) (m/z) ring Collision Transition time filtered filtered potential energy number Peptide (minutes) in Q1 in Q3 (eV) (eV) 1 AAEIGVAIVDPQGEIVAGHR 19.11 668.03 695.88 79.8 37.4 2 AAEIGVAIVDPQGEIVAGHR 19.13 668.03 731.39 79.8 37.4 3 AAEIGVAIVDPQGEIVAGHR 19.11 668.03 809.44 79.8 37.4 4 AAQIGVAIVDPQGEIVAGHR 18.76 667.70 695.88 79.8 37.4 5 AAQIGVAIVDPQGEIVAGHR 18.76 667.70 731.39 79.8 37.4 6 AAQIGVAIVDPQGEIVAGHR 18.76 667.70 809.44 79.8 37.4 7 DTTTPIAMAR 14.23 538.77 658.37 70.4 28.7 8 DTTTPIAMAR 14.23 538.77 759.42 70.4 28.7 9 DTTTPIAMAR 14.23 538.77 860.47 70.4 28.7 10 DWVVGEK 14.41 416.71 432.25 61.5 23.3 11 DWVVGEK 14.43 416.71 531.31 61.5 23.3 12 DWVVGEK 14.45 416.71 717.39 61.5 23.3 13 DYAVAVYTTAPK 15.83 649.84 680.36 78.5 33.6 14 DYAVAVYTTAPK 15.83 649.84 779.43 78.5 33.6 15 DYAVAVYTTAPK 15.85 649.84 850.47 78.5 33.6 16 EIGGPAAMTQYFR 20.03 720.85 1198.57 83.7 36.7 17 EIGGPAAMTQYFR 20.03 720.85 845.40 83.7 36.7 18 EIGGPAAMTQYFR 20.03 720.85 916.44 83.7 36.7 19 EPEMGDNTPGDLR 13.53 715.81 557.30 83.3 36.5 20 EPEMGDNTPGDLR 13.53 715.81 772.40 83.3 36.5 21 EPEMGDNTPGDLR 13.53 715.81 944.44 83.3 36.5 22 ESEMSDNTPGDLR 12.72 725.81 557.30 84 36.9 23 ESEMSDNTPGDLR 12.7 725.81 887.42 84 36.9 24 ESEMSDNTPGDLR 12.71 725.81 974.45 84 36.9 25 FAMCSTFK 16.14 496.22 642.29 67.3 26.8 26 FAMCSTFK 16.12 496.22 773.33 67.3 26.8 27 FAMCSTFK 16.12 496.22 844.37 67.3 26.8 28 FIHALLLAGIAHSAYASEK 20.93 671.37 1204.60 80.1 37.6 29 FIHALLLAGIAHSAYASEK 20.92 671.37 807.95 80.1 37.6 30 FIHALLLAGIAHSAYASEK 20.93 671.37 876.48 80.1 37.6 31 FIHALLLAGTAHSAYASEK 18.21 667.36 766.41 79.8 37.4 32 FIHALLLAGTAHSAYASEK 18.21 667.36 801.93 79.8 37.4 33 FIHALLLAGTAHSAYASEK 18.21 667.36 870.46 79.8 37.4 34 FPLAALVFER 24.46 581.84 734.42 73.5 30.6 35 FPLAALVFER 24.46 581.84 805.46 73.5 30.6 36 FPLAALVFER 24.44 581.84 918.54 73.5 30.6 37 IDSGTER 1.66 389.19 462.23 59.5 22.1 38 IDSGTER 1.84 389.19 549.26 59.5 22.1 39 IDSGTER 1.75 389.19 664.29 59.5 22.1 40 IGDSVSR 8.48 367.20 448.25 57.9 21.2 41 IGDSVSR 8.46 367.20 563.28 57.9 21.2 42 IGDSVSR 8.44 367.20 620.30 57.9 21.2 43 LSAVER 9.1 337.70 403.23 55.7 19.9 44 LSAVER 9.08 337.70 474.27 55.7 19.9 45 LSAVER 9.1 337.70 561.30 55.7 19.9 46 LSYGPDMIVEWSPATER 22.31 650.98 573.30 78.6 36.5 47 LSYGPDMIVEWSPATER 22.29 650.98 660.33 78.6 36.5 48 LSYGPDMIVEWSPATER 22.26 650.98 846.41 78.6 36.5 49 LSYGPDMIVK 17.71 561.80 1009.50 72.1 29.7 50 LSYGPDMIVK 17.69 561.80 759.41 72.1 29.7 51 LSYGPDMIVK 17.69 561.80 922.47 72.1 29.7 52 NDIGFFK 17.71 420.72 498.27 61.8 23.5 53 NDIGFFK 17.69 420.72 611.36 61.8 23.5 54 NDIGFFK 17.74 420.72 726.38 61.8 23.5 55 TDLEK 3.66 303.16 389.24 53.2 18.3 56 TDLEK 3.73 303.16 459.21 53.2 18.3 57 TDLEK 3.6 303.16 504.27 53.2 18.3 58 TGACANGAR 1.48 439.20 648.29 63.1 24.3 59 TGACANGAR 1.48 439.20 719.33 63.1 24.3 60 TGACANGAR 1.48 439.20 776.35 63.1 24.3 61 TGTCANGAR 1.48 454.21 648.29 64.2 25 62 TGTCANGAR 1.48 454.21 749.34 64.2 25 63 TGTCANGAR 1.48 454.21 806.36 64.2 25 64 TGTCANGGR 1.48 447.20 474.24 63.7 24.7 65 TGTCANGGR 1.48 447.20 634.27 63.7 24.7 66 TGTCANGGR 1.48 447.20 735.32 63.7 24.7 67 VLYGGALTSTSTHTIER 15.87 602.65 1245.64 75.1 34.1 68 VLYGGALTSTSTHTIER 15.85 602.65 715.87 75.1 34.1 69 VLYGGALTSTSTHTIER 15.87 602.65 797.40 75.1 34.1 70 WLIGNQTGDATLR 18.93 722.88 1032.51 83.8 36.8 71 WLIGNQTGDATLR 19.02 722.88 1145.59 83.8 36.8 72 WLIGNQTGDATLR 18.96 722.88 733.38 83.8 36.8 73 WSPATER 11.37 423.71 476.25 62 23.6 74 WSPATER 11.37 423.71 573.30 62 23.6 75 WSPATER 11.34 423.71 660.33 62 23.6

-   -   The other machine parameters used are as follows:     -   Scan type: MRM     -   MRM planned: yes     -   Polarity: Positive     -   Ionising source: Turbo V™ (Applied BioSystems)     -   Q1 setting: Filtering with unit resolution     -   Q3 setting: Filtering with unit resolution     -   Inter-scan pause: 5.00 msec     -   Scanning speed: 10 Da/s     -   Curtain gas: 40.00 psi     -   Cone voltage: 5500.00 V     -   Source temperature: 500.00° C.     -   Nebulising gas: 50.00 psi     -   Heating gas: 50.00 psi     -   Collision gas which induces dissociation: 9.00 psi     -   Dynamic filling: activated     -   Entry potential before Q0 (EP): 10.00 V     -   Collision cell exit potential (CXP): 15.00 V

The areas obtained for each of the transitions and for each of the microorganisms studied were measured. When the areas of the transitions are greater than or equal to the positivity threshold described in TABLE 16, the detection of the transition is considered to be positive and is labelled “1” in TABLE 17. When a transition has an area less than the positivity threshold described in TABLE 16, the transition is considered non-detected and is labelled “0” in TABLE 17.

For a given peptide, when at least 3 transitions are labelled “1”, the peptide is considered as being detected.

TABLE 17 Transition number Sam89 Sam90 1 0 0 2 0 0 3 0 0 4 0 0 5 1 1 6 0 0 7 1 1 8 1 1 9 1 1 10 1 1 11 1 1 12 1 1 13 0 0 14 0 0 15 0 0 16 0 0 17 0 0 18 0 0 19 0 0 20 0 0 21 0 0 22 0 0 23 0 0 24 0 0 25 0 0 26 0 0 27 0 0 28 0 0 29 0 0 30 0 0 31 0 0 32 0 0 33 0 0 34 0 0 35 0 0 36 0 0 37 1 1 38 1 1 39 1 1 40 1 1 41 1 1 42 1 1 43 1 1 44 1 1 45 1 1 46 1 1 47 1 1 48 1 1 49 0 0 50 0 0 51 0 0 52 1 1 53 1 1 54 1 1 55 0 0 56 0 0 57 0 0 58 0 0 59 0 0 60 0 0 61 0 0 62 0 0 63 0 0 64 1 0 65 0 1 66 1 1 67 1 1 68 1 1 69 1 1 70 1 1 71 1 1 72 1 1 73 0 0 74 0 0 75 0 0

Samples Sam89 and Sam90 comprise at least one peptide which is characteristic of the carbapenemase phenotype. The bacteria present in samples Sam89 to Sam90 therefore express a beta-lactamase which confers on them a resistance to penicillins, to cephalosporins and to carbapenems.

EXAMPLE 11 Identification of a Resistance to SME Beta-Lactams

Samples Sam91 to Sam95 are identified according to one of the methods described in examples 1, 3 or 4. The identification of the species is set out in TABLE 18.

TABLE 18 Names Species Sam91 S. marcescens Sam92 S. marcescens Sam93 S. marcescens Sam94 S. marcescens Sam95 S. marcescens

Samples Sam91 to Sam95 correspond to a species able to comprise an SME resistance mechanism. The following method is then performed to detect such a mechanism.

Each sample is treated according to Example 5, then analysed according to Example 6 unless otherwise stated in the rest of the example, by detecting the peptides from TABLE 19 instead of the peptides from TABLE 3.

TABLE 19 Retention (m/z) (m/z) Collision Transition time filtered in filtered in energy positivity number Peptide (minutes) Q1 Q3 (eV) threshold 1 AIYQNWLK 18.69 518.29 426.22 25.3 2500 2 AIYQNWLK 18.69 518.29 688.38 25.3 2500 3 AIYQNWLK 18.69 518.29 851.44 25.3 2500 4 APLIVSIYTTR 20.21 617.36 740.39 30.9 2500 5 APLIVSIYTTR 20.21 617.36 839.46 30.9 2500 6 APLIVSIYTTR 20.21 617.36 952.55 30.9 2500 7 ASVPADWVVGDK 17.56 622.32 493.75 31.2 2500 8 ASVPADWVVGDK 17.56 622.32 543.29 31.2 2500 9 ASVPADWVVGDK 17.56 622.32 986.49 31.2 2500 10 AVANSLNK 8.75 408.73 461.27 19 2500 11 AVANSLNK 8.75 408.73 575.32 19 2500 12 AVANSLNK 8.75 408.73 646.35 19 2500 13 DLEYHSPITTK 14.48 435.22 473.75 20.6 2500 14 DLEYHSPITTK 14.48 435.22 538.28 20.6 2500 15 DLEYHSPITTK 14.48 435.22 646.38 20.6 2500 16 DLEYYSPITTK 17.4 665.33 559.35 33.7 2500 17 DLEYYSPITTK 17.4 665.33 646.38 33.7 2500 18 DLEYYSPITTK 17.4 665.33 809.44 33.7 2500 19 DTSTPK 1.45 324.66 345.21 14.2 2500 20 DTSTPK 1.45 324.66 432.25 14.2 2500 21 DTSTPK 1.45 324.66 533.29 14.2 2500 22 FLGGPEGMTK 14.94 518.76 662.32 25.3 2500 23 FLGGPEGMTK 14.94 518.76 719.34 25.3 2500 24 FLGGPEGMTK 14.94 518.76 776.36 25.3 2500 25 GFLAAAVLER 20.49 523.80 587.35 25.6 2500 26 GFLAAAVLER 20.49 523.80 658.39 25.6 2500 27 GFLAAAVLER 20.49 523.80 729.43 25.6 2500 28 GNTTGDAR 6.45 396.19 418.20 18.3 2500 29 GNTTGDAR 6.45 396.19 519.25 18.3 2500 30 GNTTGDAR 6.45 396.19 620.30 18.3 2500 31 IGVFAIDTGSGNTFGYR 21.45 592.30 542.27 25.4 2500 32 IGVFAIDTGSGNTFGYR 21.45 887.94 1174.51 46.3 2500 33 IGVFAIDTGSGNTFGYR 21.45 887.94 958.44 46.3 2500 34 LALGNVLNAK 18.56 506.81 414.75 24.6 2500 35 LALGNVLNAK 18.56 506.81 715.41 24.6 2500 36 LALGNVLNAK 18.56 506.81 828.49 24.6 2500 37 LDINQK 10.3 365.71 389.21 16.6 2500 38 LDINQK 10.3 365.71 502.30 16.6 2500 39 LDINQK 10.3 365.71 617.33 16.6 2500 40 LEEDFDGR 12.51 490.72 609.26 23.7 2500 41 LEEDFDGR 12.51 490.72 738.31 23.7 2500 42 LEEDFDGR 12.51 490.72 867.35 23.7 2500 43 SDAAAK 7.06 281.65 289.19 11.8 2500 44 SDAAAK 7.06 281.65 360.22 11.8 2500 45 SDAAAK 7.06 281.65 475.25 11.8 2500 46 SIGDNEFR 12.81 469.22 565.27 22.5 2500 47 SIGDNEFR 12.81 469.22 680.30 22.5 2500 48 SIGDNEFR 12.81 469.22 737.32 22.5 2500 49 TGSCGAIGTANDYAVIWPK 20.29 660.99 430.25 27.6 2500 50 TGSCGAIGTANDYAVIWPK 20.29 660.99 713.43 27.6 2500 51 TGSCGAIGTANDYAVIWPK 20.29 990.98 430.25 52.2 2500 52 TGSCGAYGTANDYAVIWPK 19.78 1015.97 430.25 53.6 2500 53 TGSCGAYGTANDYAVIWPK 19.78 677.65 642.40 28.1 2500 54 TGSCGAYGTANDYAVIWPK 19.78 677.65 713.43 28.1 2500 55 TIAEASR 6.98 374.20 333.19 17.1 2500 56 TIAEASR 6.98 374.20 462.23 17.1 2500 57 TIAEASR 6.98 374.20 646.35 17.1 2500 58 WELELNTAIPGDK 21.06 495.92 416.21 22.5 2500 59 WELELNTAIPGDK 21.06 743.38 1170.64 38.1 2500 60 WELELNTAIPGDK 21.06 743.38 416.21 38.1 2500

-   -   The other machine parameters used are as follows:     -   Scan type: MRM     -   MRM planned: yes     -   Polarity: Positive     -   Ionising source: Turbo V™ (Applied BioSystems)     -   Q1 setting: Filtering with unit resolution     -   Q3 setting: Filtering with unit resolution     -   Inter-scan pause: 5.00 msec     -   Scanning speed: 10 Da/s     -   Curtain gas: 40.00 psi     -   Cone voltage: 5500.00 V     -   Source temperature: 500.00° C.     -   Nebulising gas: 50.00 psi     -   Heating gas: 50.00 psi     -   Collision gas which induces dissociation: 9.00 psi     -   Dynamic filling: activated     -   Declustering potential (DP): 100.00 V     -   Entry potential before Q0 (EP): 10.00 V     -   Collision cell exit potential (CXP): 15.00 V

The areas obtained for each of the transitions and for each of the microorganisms studied were measured. When the areas of the transitions are greater than or equal to the positivity threshold described in TABLE 19, the detection of the transition is considered to be positive and is labelled “1” in TABLE 20. When a transition has an area less than the positivity threshold described in TABLE 19, the transition is considered non-detected and is labelled “0” in TABLE 20.

For a given peptide, when at least 3 transitions are labelled “1”, the peptide is considered as being detected.

TABLE 20 Transition number Sam91 Sam92 Sam93 Sam94 Sam95 1 0 1 0 0 0 2 1 1 0 0 1 3 0 1 0 0 0 4 0 0 0 0 0 5 0 0 0 0 0 6 0 0 0 0 0 7 1 1 1 1 1 8 1 1 1 1 1 9 1 1 1 1 1 10 1 1 1 1 1 11 1 1 1 1 1 12 1 1 1 1 1 13 1 1 1 1 1 14 1 1 1 1 1 15 1 1 1 1 1 16 0 0 0 0 0 17 0 0 0 0 0 18 0 0 0 0 0 19 0 0 0 0 0 20 0 0 0 0 0 21 0 0 0 0 0 22 1 1 1 0 1 23 1 1 1 0 1 24 1 1 1 0 1 25 1 1 1 1 1 26 1 1 1 1 1 27 1 1 1 1 1 28 0 0 0 0 0 29 0 0 0 0 0 30 0 0 0 0 0 31 0 0 0 0 0 32 0 0 0 0 0 33 0 0 0 0 0 34 1 1 1 1 1 35 1 1 1 1 1 36 1 1 1 1 1 37 0 0 0 0 0 38 0 0 0 0 0 39 0 0 0 0 0 40 1 1 1 0 1 41 1 1 1 0 1 42 1 1 1 0 1 43 0 0 0 0 0 44 0 0 0 0 0 45 0 0 0 0 0 46 0 0 1 0 0 47 0 0 1 0 0 48 0 0 1 0 0 49 0 0 0 0 0 50 0 0 0 0 0 51 0 0 0 0 0 52 0 0 0 0 0 53 0 0 0 0 0 54 0 0 0 0 0 55 0 0 0 0 0 56 0 0 0 0 0 57 0 0 0 0 0 58 0 0 0 0 0 59 0 0 0 0 0 60 0 0 0 0 0

Samples Sam91 to Sam95 comprise at least one peptide which is characteristic of SMEs. The bacteria present in samples Sam91 to Sam95 therefore express a beta-lactamase which confers on them a resistance to penicillins, to cephalosporins and to carbapenems.

EXAMPLE 12 Identification of a Resistance to IMP Beta-Lactams

The samples corresponding to a species able to comprise an IMP resistance mechanism can be detected by employing the following method.

Each sample is treated according to Example 5, then analysed according to Example 6 by detecting the peptides from TABLE 21 instead of the peptides from TABLE 3.

TABLE 21 (m/z) (m/z) Transition Retention time filtered in filtered in Collision number Peptide (minutes) Q1 Q3 energy (eV) 1 EVNGWGVVPK 16.02 542.79 742.35 29 2 EVNGWGVVPK 16.02 542.79 856.47 29 3 EVNGWGVVPK 16.02 542.79 955.54 29 4 GSISSHFHSDSTGGIGWLNSR 16.97 551.26 675.36 31 5 GSISSHFHSDSTGGIGWLNSR 16.97 551.26 732.38 31 6 GSISSHFHSDSTGGIGWLNSR 16.97 734.68 959.51 41 7 HGLVILVNTDAYLIDTPFTAK 24.53 767.75 892.48 42 8 HGLVILVNTDAYLIDTPFTAK 24.53 767.75 1005.56 42 9 HGLVILVNTDAYLIDTPFTAK 24.53 767.75 1133.63 42 10 HGLVVLVNNDAYLIDTPFTNK 22.75 781.75 822.4 43 11 HGLWLVNNDAYLIDTPFTNK 22.75 781.75 935.48 43 12 HGLVVLVNNDAYLIDTPFTNK 22.75 781.75 1132.61 43 13 HGLVVLVNTDAYLIDTPFTAK 23.91 763.08 779.39 42 14 HGLVVLVNTDAYLIDTPFTAK 23.91 763.08 892.48 42 15 HGLVVLVNTDAYLIDTPFTAK 23.91 763.08 1119.62 42 16 HGLVVLVNTEAYLIDTPFTAK 24.53 767.75 779.39 42 17 HGLVVLVNTEAYLIDTPFTAK 24.53 767.75 892.48 42 18 HGLVVLVNTEAYLIDTPFTAK 24.53 767.75 1133.63 42 19 IEVFYPGPGHTQDNVVVWLPK 22.25 599.57 642.4 33 20 IEVFYPGPGHTQDNVVVWLPK 22.25 599.57 741.47 33 21 IEVFYPGPGHTQDNVVVWLPK 22.25 799.09 872.46 44 22 ILMEK 11.28 317.19 407.2 19 23 ILMEK 11.28 317.19 487.26 19 24 ILMEK 11.28 317.19 520.28 19 25 ILMSK 10.48 296.18 365.19 18 26 ILMSK 10.48 296.18 445.25 18 27 ILMSK 10.48 296.18 478.27 18 28 LDEGVYVHTSFK 15.03 465.57 482.26 27 29 LDEGVYVHTSFK 15.03 465.57 619.32 27 30 LDEGVYVHTSFK 15.03 465.57 881.45 27 31 LEEGVYVHTSYEEVK 14.55 594.62 855.41 34 32 LEEGVYVHTSYEEVK 14.55 594.62 992.47 34 33 LEEGVYVHTSYEEVK 14.55 891.43 992.47 44 34 LLISK 12.19 287.2 347.23 18 35 LLISK 12.19 287.2 427.29 18 36 LLISK 12.19 287.2 460.31 18 37 LLMSK 11.18 296.18 365.19 18 38 LLMSK 11.18 296.18 445.25 18 39 LLMSK 11.18 296.18 478.27 18 40 LLVSK 10.48 280.19 333.21 17 41 LLVSK 10.48 280.19 413.28 17 42 LLVSK 10.48 280.19 446.3 17 43 LPDLK 12.56 293.18 375.22 18 44 LPDLK 12.56 293.18 439.26 18 45 LPDLK 12.56 293.18 472.28 18 46 LVVSGHSETGDATHLK 11.41 413.47 569.34 24 47 LVVSGHSETGDATHLK 11.41 550.95 719.85 32 48 LVVSGHSETGDATHLK 11.41 550.95 1058.51 32 49 NSFDGVSYVVLAK 20.75 693.84 767.41 36 50 NSFDGVSYWLAK 20.75 693.84 1038.53 36 51 NSFDGVSYWLAK 20.75 693.84 1185.59 36

The areas obtained for each of the transitions and for each of the microorganisms studied were measured. When the areas of the three transitions of the same peptide are greater than or equal to 2500, the detection of the peptide is considered to be positive and is labelled “1”. When at least one transition comprises an area less than 2500, the corresponding peptide is considered non-detected and is labelled “0”.

EXAMPLE 13 Identification of a Resistance to KPC Beta-Lactams

The samples corresponding to a species able to comprise a KPC resistance mechanism can be detected by employing the following method.

Each sample is treated according to Example 5, then analysed according to Example 6 by detecting the peptides from TABLE 22 instead of the peptides from TABLE 3.

TABLE 22 Retention (m/z) (m/z) Collision Transition time filtered in filtered in energy number Peptide (minutes) Q1 Q3 (eV) 1 NALVR 8.14 286.68 387.27 18 2 NALVR 8.14 286.68 398.24 18 3 NALVR 8.14 286.68 458.31 18 4 TGTC[CAM]GAYGTANDYAVVWPTGR 18.76 739.67 1169.45 41 5 TGTC[CAM]GAYGTANDYAVVWPTGR 18.76 1109.01 1163.58 54 6 TGTC[CAM]GAYGTANDYAVVWPTGR 18.76 1109.01 1169.45 54 7 WELELNSAIPSDAR 20.43 534.27 545.27 31 8 WELELNSAIPSDAR 20.43 800.9 930.46 40 9 WELELNSAIPSDAR 20.43 800.9 1043.55 40 10 WELEMNSAIPGDAR 19.35 794.87 900.45 40 11 WELEMNSAIPGDAR 19.35 794.87 1031.49 40 12 WELEMNSAIPGDAR 19.35 794.87 1074.49 40

The areas obtained for each of the transitions and for each of the microorganisms studied were measured. When the areas of the three transitions of the same peptide are greater than or equal to 2500, the detection of the peptide is considered to be positive and is labelled “1”. When at least one transition comprises an area less than 2500, the corresponding peptide is considered non-detected and is labelled “0”.

EXAMPLE 14 Identification of a Resistance to NDM Beta-Lactams

The samples corresponding to a species able to comprise an NDM resistance mechanism can be detected by employing the following method.

Each sample is treated according to Example 5, then analysed according to Example 6 by detecting the peptides from TABLE 23 instead of the peptides from TABLE 3.

TABLE 23 (m/z) (m/z) Transition Retention time filtered in filtered in Collision number Peptide (minutes) Q1 Q3 energy (eV) 1 VLLVDTAWTDDQTAQILNWIK 27.87 815.1 914.55 45 2 VLLVDTAWTDDQTAQILNWIK 27.86 815.1 985.58 45 3 VLLVDTAWTDDQTAQILNWIK 27.85 815.1 1086.63 45

The areas obtained for each of the transitions and for each of the microorganisms studied were measured. When the areas of the three transitions of the same peptide are greater than or equal to 2500, the detection of the peptide is considered to be positive and is labelled “1”. When at least one transition comprises an area less than 2500, the corresponding peptide is considered non-detected and is labelled “0”.

EXAMPLE 15 Identification of a Resistance to VIM Beta-Lactams

The samples corresponding to a species able to comprise a VIM resistance mechanism can be detected by employing the following method.

Each sample is treated according to Example 5, then analysed according to Example 6 by detecting the peptides from TABLE 24 instead of the peptides from TABLE 3.

TABLE 24 (m/z) (m/z) Transition Retention time filtered in filtered in Collision number Peptide (minutes) Q1 Q3 energy (eV) 1 LANEIPTHSLEGLSSSGDAVR 16.72 718.37 778.37 40 2 LANEIPTHSLEGLSSSGDAVR 16.72 718.37 948.47 40 3 LANEIPTHSLEGLSSSGDAVR 16.72 718.37 1077.52 40

The areas obtained for each of the transitions and for each of the microorganisms studied were measured. When the areas of the three transitions of the same peptide are greater than or equal to 2500, the detection of the peptide is considered to be positive and is labelled “1”. When at least one transition comprises an area less than 2500, the corresponding peptide is considered non-detected and is labelled “0”.

EXAMPLE 16 Identification of a Resistance to OXA Beta-Lactams

The samples corresponding to a species able to comprise an OXA resistance mechanism can be detected by employing the following method.

Each sample is treated according to Example 5, then analysed according to Example 6 by detecting the peptides from TABLE 25 instead of the peptides from TABLE 3.

TABLE 25 Retention (m/z) (m/z) Collision Transition time filtered in filtered in energy number Peptide (minutes) Q1 Q3 (eV) 1 AAAYELAENLFEAGQADGWR 24.48 728.01 1249.6 40 2 AAAYELAENLFEAGQADGWR 24.48 1091.51 1193.58 53 3 AAAYELAENLFEAGQADGWR 24.48 1091.51 1249.6 53 4 AAEGFIPASTFK 17.74 619.82 763.43 32 5 AAEGFIPASTFK 17.74 619.82 910.5 32 6 AAEGFIPASTFK 17.74 619.82 967.52 32 7 ADGQVVAFALNMQMK 21.27 811.91 982.48 41 8 ADGQVVAFALNMQMK 21.29 811.91 1053.52 41 9 ADGQVVAFALNMQMK 21.27 811.91 1152.59 41 10 ADINEIFK 17.3 475.25 650.35 26 11 ADINEIFK 17.3 475.25 763.43 26 12 ADINEIFK 17.3 475.25 878.46 26 13 ADWGK 6.9 288.64 390.21 18 14 ADWGK 6.91 288.64 430.17 18 15 ADWGK 6.89 288.64 505.24 18 16 AEGAIVISDER 13.52 387.2 419.19 23 17 AEGAIVISDER 13.53 387.2 506.22 23 18 AEGAIVISDER 13.52 387.2 619.3 23 19 AFALNLDIDK 20.16 560.31 717.38 30 20 AFALNLDIDK 20.16 560.31 830.46 30 21 AFALNLDIDK 20.16 560.31 901.5 30 22 AFAPMSTFK 16.96 500.25 710.35 27 23 AFAPMSTFK 16.96 500.25 781.39 27 24 AFAPMSTFK 16.96 500.25 928.46 27 25 AFGYGNADVSGDPGQNNGLDR 15.12 708.65 873.42 39 26 AFGYGNADVSGDPGQNNGLDR 15.12 708.65 970.47 39 27 AFGYGNADVSGDPGQNNGLDR 15.12 708.65 1154.47 39 28 AFTMTK 11.32 349.68 480.25 20 29 AFTMTK 11.33 349.68 552.25 20 30 AFTMTK 11.33 349.68 627.32 20 31 AGDDIALR 12.23 415.72 587.35 23 32 AGDDIALR 12.23 415.72 702.38 23 33 AGDDIALR 12.23 415.72 759.4 23 34 AGHVYAFALNIDMPR 20.63 558.95 631.32 32 35 AGHVYAFALNIDMPR 20.63 558.95 745.37 32 36 AGHVYAFALNIDMPR 20.63 558.95 817.4 32 37 AGLWR 13.44 301.67 361.2 18 38 AGLWR 13.44 301.67 474.28 18 39 AGLWR 13.44 301.67 531.3 18 40 AHTEYVPASTFK 13.18 450.89 553.3 27 41 AHTEYVPASTFK 13.18 450.89 602.26 27 42 AHTEYVPASTFK 13.18 450.89 650.35 27 43 AIIPWDGKPR 15.84 384.89 428.23 23 44 AIIPWDGKPR 15.84 384.89 457.29 23 45 AIIPWDGKPR 15.84 384.89 572.32 23 46 AISDITITR 14.8 495.28 603.38 27 47 AISDITITR 14.8 495.28 718.41 27 48 AISDITITR 14.8 495.28 805.44 27 49 ALGQDR 11.25 330.18 475.23 20 50 ALGQDR 11.25 330.18 485.24 20 51 ALGQDR 11.25 330.18 588.31 20 52 ALQAK 1.86 265.67 346.21 17 53 ALQAK 1.87 265.67 384.22 17 54 ALQAK 1.87 265.67 459.29 17 55 AMETFSPASTFK 17.06 658.81 737.38 34 56 AMETFSPASTFK 17.05 658.81 985.5 34 57 AMETFSPASTFK 17.06 658.81 1114.54 34 58 AMLFLQER 18.48 504.27 545.3 27 59 AMLFLQER 18.48 504.27 692.37 27 60 AMLFLQER 18.48 504.27 805.46 27 61 AMLVFDPVR 19.87 524.29 732.4 28 62 AMLVFDPVR 19.87 524.29 845.49 28 63 AMLVFDPVR 19.87 524.29 976.53 28 64 AMTLLESGPGWELHGK 19.32 575.96 923.47 33 65 AMTLLESGPGWELHGK 19.32 575.96 980.49 33 66 AMTLLESGPGWELHGK 19.32 575.96 1067.53 33 67 ANLHITLHGK 12.18 368.55 403.24 22 68 ANLHITLHGK 12.18 368.55 555.32 22 69 ANLHITLHGK 12.18 368.55 668.41 22 70 ANQLIVK 11.87 393.25 600.41 22 71 ANQLIVK 11.86 393.25 639.38 22 72 ANQLIVK 11.86 393.25 714.45 22 73 ANTEYVPASTFK 14.54 664.33 912.48 34 74 ANTEYVPASTFK 14.54 664.33 1041.53 34 75 ANTEYVPASTFK 14.54 664.33 1142.57 34 76 ANVSR 9.57 273.65 361.22 17 77 ANVSR 9.57 273.65 372.19 17 78 ANVSR 9.57 273.65 475.26 17 79 APIGWFIGWATR 25.58 687.87 850.46 35 80 APIGWFIGWATR 25.58 687.87 1093.56 35 81 APIGWFIGWATR 25.58 687.87 1206.64 35 82 APLGWFIGWATHEER 24.69 590.63 742.35 34 83 APLGWFIGWATHEER 24.69 590.63 985.45 34 84 APLGWFIGWATHEER 24.69 590.63 1098.53 34 85 AQDEVQSMLFIEEK 20.15 833.9 996.51 42 86 AQDEVQSMLFIEEK 20.14 833.9 1124.57 42 87 AQDEVQSMLFIEEK 20.15 833.9 1223.63 42 88 AQGVIVLWNENK 18.95 685.87 902.47 35 89 AQGVIVLWNENK 18.95 685.87 1015.56 35 90 AQGVIVLWNENK 18.95 685.87 1171.65 35 91 ASAIAVYQDLAR 18.05 639.35 765.39 33 92 ASAIAVYQDLAR 18.05 639.35 864.46 33 93 ASAIAVYQDLAR 18.05 639.35 935.49 33 94 ASAILVYQDLAR 19.08 660.37 765.39 34 95 ASAILVYQDLAR 19.08 660.37 864.46 34 96 ASAILVYQDLAR 19.08 660.37 977.54 34 97 ASAIPVYQDLAR 17.45 652.35 765.39 34 98 ASAIPVYQDLAR 17.45 652.35 864.46 34 99 ASAIPVYQDLAR 17.45 652.35 961.51 34 100 ASAIPVYQDLPR 17.59 665.36 791.4 34 101 ASAIPVYQDLPR 17.59 665.36 890.47 34 102 ASAIPVYQDLPR 17.6 665.36 987.53 34 103 ASAIQVYQDLAR 18.37 667.86 765.39 34 104 ASAIQVYQDLAR 18.37 667.86 864.46 34 105 ASAIQVYQDLAR 18.37 667.86 992.52 34 106 ASAISVYQDLAR 17.93 647.34 765.39 33 107 ASAISVYQDLAR 17.93 647.34 864.46 33 108 ASAISVYQDLAR 17.93 647.34 951.49 33 109 ASALPVYQDLAR 17.77 652.35 864.46 34 110 ASALPVYQDLAR 17.77 652.35 961.51 34 111 ASALPVYQDLAR 17.77 652.35 1074.59 34 112 ASAMPVYQDLAR 16.64 661.33 765.39 34 113 ASAMPVYQDLAR 16.64 661.33 864.46 34 114 ASAMPVYQDLAR 16.64 661.33 961.51 34 115 ASAVPVYQDLAR 16.29 645.35 765.39 33 116 ASAVPVYQDLAR 16.29 645.35 864.46 33 117 ASAVPVYQDLAR 16.29 645.35 961.51 33 118 ASIEYVPASTFK 16.7 656.84 749.42 34 119 ASIEYVPASTFK 16.7 656.84 912.48 34 120 ASIEYVPASTFK 16.7 656.84 1041.53 34 121 ASNVPVYQELAR 18.48 673.86 779.4 35 122 ASNVPVYQELAR 18.48 673.86 878.47 35 123 ASNVPVYQELAR 18.48 673.86 975.53 35 124 ASPASTFK 10.29 404.71 553.3 23 125 ASPASTFK 10.29 404.71 650.35 23 126 ASPASTFK 10.28 404.71 737.38 23 127 ASTAYIPASTFK 15.69 628.83 763.43 33 128 ASTAYIPASTFK 15.69 628.83 926.5 33 129 ASTAYIPASTFK 15.69 628.83 997.54 33 130 ASTEYVPASTFK 14.59 650.82 749.42 34 131 ASTEYVPASTFK 14.59 650.82 912.48 34 132 ASTEYVPASTFK 14.6 650.82 1041.53 34 133 ASTTEVFK 11.78 441.73 623.34 24 134 ASTTEVFK 11.78 441.73 724.39 24 135 ASTTEVFK 11.78 441.73 811.42 24 136 ATSTEIFK 13.15 448.74 637.36 25 137 ATSTEIFK 13.15 448.74 724.39 25 138 ATSTEIFK 13.15 448.74 825.44 25 139 ATTNEIFK 13.21 462.25 650.35 25 140 ATTNEIFK 13.21 462.25 751.4 25 141 ATTNEIFK 13.21 462.25 852.45 25 142 ATTTAVFK 11.9 419.74 464.29 23 143 ATTTAVFK 11.9 419.74 565.33 23 144 ATTTAVFK 11.9 419.74 666.38 23 145 ATTTEIFK 13.64 455.75 637.36 25 146 ATTTEIFK 13.65 455.75 738.4 25 147 ATTTEIFK 13.65 455.75 839.45 25 148 ATTTEVFK 11.98 448.74 623.34 25 149 ATTTEVFK 11.98 448.74 724.39 25 150 ATTTEVFK 11.98 448.74 825.44 25 151 AVSDITILEQTDNYTLHGK 19.19 706.7 974.49 39 152 AVSDITILEQTDNYTLHGK 19.19 706.7 1048.51 39 153 AVSDITILEQTDNYTLHGK 19.18 706.7 1176.56 39 154 AVSDITILEQTYNYTLHGK 22.29 722.71 995.49 40 155 AVSDITILEQTYNYTLHGK 22.29 722.71 998.5 40 156 AVSDITILEQTYNYTLHGK 22.28 722.71 1224.6 40 157 AVVPHFEAGDWDVQGK 17.81 585.62 743.34 33 158 AVVPHFEAGDWDVQGK 17.81 585.62 792.88 33 159 AVVPHFEAGDWDVQGK 17.81 585.62 904.42 33 160 AWEHDMSLR 13.99 572.76 758.36 30 161 AWEHDMSLR 13.99 572.76 887.4 30 162 AWEHDMSLR 13.99 572.76 1073.48 30 163 AWIGSSLQISPLEQLEFLGK 26.98 739.4 963.51 41 164 AWIGSSLQISPLEQLEFLGK 26.99 739.4 1173.65 41 165 AWIGSSLQISPLEQLEFLGK 26.98 1108.6 1173.65 54 166 DAFLK 12.42 297.17 407.27 18 167 DAFLK 12.43 297.17 447.22 18 168 DAFLK 12.42 297.17 478.3 18 169 DDFILHGK 13.99 472.75 714.43 26 170 DDFILHGK 13.99 472.75 798.38 26 171 DDFILHGK 13.99 472.75 829.46 26 172 DDVLK 8.62 295.16 359.27 18 173 DDVLK 8.63 295.16 443.21 18 174 DDVLK 8.62 295.16 474.29 18 175 DEFHVFR 15.39 475.23 705.38 26 176 DEFHVFR 15.39 475.23 775.34 26 177 DEFHVFR 15.39 475.23 834.43 26 178 DEFQIFR 19.02 477.74 520.2 26 179 DEFQIFR 19.02 477.74 563.33 26 180 DEFQIFR 19.02 477.74 710.4 26 181 DEFQVFR 17.29 470.73 549.31 26 182 DEFQVFR 17.28 470.73 619.27 26 183 DEFQVFR 17.29 470.73 696.38 26 184 DELVR 9.33 316.17 387.27 19 185 DELVR 9.35 316.17 457.23 19 186 DELVR 9.33 316.17 516.31 19 187 DFDYGNQDFSGDK 14.72 754.3 967.41 38 188 DFDYGNQDFSGDK 14.72 754.3 1130.47 38 189 DFDYGNQDFSGDK 14.72 754.3 1245.5 38 190 DFTLGEAMQASTVPVYQELAR 24.19 776.05 975.53 43 191 DFTLGEAMQASTVPVYQELAR 24.19 776.05 1074.59 43 192 DFTLGEAMQASTVPVYQELAR 24.19 1163.57 1175.64 56 193 DHDLITAMK 14.23 522.26 563.32 28 194 DHDLITAMK 14.23 522.26 695.34 28 195 DHDLITAMK 14.23 522.26 791.43 28 196 DIAAWNR 13.63 423.22 546.28 24 197 DIAAWNR 13.63 423.22 617.32 24 198 DIAAWNR 13.62 423.22 730.4 24 199 DILYIQELAGGWK 24.49 753.4 888.46 38 200 DILYIQELAGGWK 24.48 753.4 1001.54 38 201 DILYIQELAGGWK 24.49 753.4 1164.6 38 202 DITILEK 15.9 416.24 603.37 23 203 DITILEK 15.91 416.24 685.38 23 204 DITILEK 15.91 416.24 716.46 23 205 DLLSAK 12.45 323.69 429.23 19 206 DLLSAK 12.44 323.69 500.27 19 207 DLLSAK 12.45 323.69 531.35 19 208 DLMITEAGR 15.07 503.26 533.27 27 209 DLMITEAGR 15.07 503.26 646.35 27 210 DLMITEAGR 15.07 503.26 777.39 27 211 DLMIVEAGR 16.68 502.27 531.29 27 212 DLMIVEAGR 16.68 502.27 644.37 27 213 DLMIVEAGR 16.68 502.27 775.41 27 214 DLMIVEAK 16.23 459.75 473.24 25 215 DLMIVEAK 16.23 459.75 559.34 25 216 DLMIVEAK 16.23 459.75 690.39 25 217 DLSGNPGK 6.69 394.2 472.25 22 218 DLSGNPGK 6.69 394.2 559.28 22 219 DLSGNPGK 6.7 394.2 672.37 22 220 DLSLR 12.37 302.18 375.24 18 221 DLSLR 12.35 302.18 429.23 18 222 DLSLR 12.36 302.18 488.32 18 223 DLTLR 12.48 309.18 389.25 19 224 DLTLR 12.47 309.18 443.25 19 225 DLTLR 12.47 309.18 502.33 19 226 DMTLGDAIK 15.97 482.24 503.28 26 227 DMTLGDAIK 15.97 482.24 616.37 26 228 DMTLGDAIK 15.97 482.24 717.41 26 229 DMTLGDAMALSAVPVYQELAR 25.76 751.04 975.53 42 230 DMTLGDAMALSAVPVYQELAR 25.76 1126.06 1145.63 55 231 DMTLGDAMALSAVPVYQELAR 25.75 1126.06 1232.66 55 232 DMTLGDAMK 14.46 491.22 634.32 27 233 DMTLGDAMK 14.46 491.22 735.37 27 234 DMTLGDAMK 14.46 491.22 866.41 27 235 DMTLGEAMALSAVPVYQDLAR 25.92 751.04 961.51 42 236 DMTLGEAMALSAVPVYQDLAR 25.92 1126.06 1131.62 55 237 DMTLGEAMALSAVPVYQDLAR 25.92 1126.06 1218.65 55 238 DMTLGEAMALSAVPVYQELAR 26.48 755.71 779.4 42 239 DMTLGEAMALSAVPVYQELAR 26.48 755.71 975.53 42 240 DMTLGEAMALSAVPVYQELAR 26.47 1133.07 1232.66 55 241 DMTLGEAMK 15.09 498.23 535.25 27 242 DMTLGEAMK 15.09 498.23 648.34 27 243 DMTLGEAMK 15.09 498.23 749.39 27 244 DMTLGQAMQASAVPVYQELAR 23.29 760.38 779.4 42 245 DMTLGQAMQASAVPVYQELAR 23.29 760.38 975.53 42 246 DMTLGQAMQASAVPVYQELAR 23.29 760.38 976.42 42 247 DQDLR 2.54 323.66 403.23 19 248 DQDLR 2.55 323.66 472.2 19 249 DQDLR 2.55 323.66 531.29 19 250 DQQIGWFVGWASKPGK 21.64 601.98 830.45 34 251 DQQIGWFVGWASKPGK 21.64 902.46 929.52 45 252 DQQIGWFVGWASKPGK 21.64 902.46 1076.59 45 253 DQQVQVYGNDLNR 13.59 774.87 851.4 39 254 DQQVQVYGNDLNR 13.58 774.87 950.47 39 255 DQQVQVYGNDLNR 13.59 774.87 1078.53 39 256 DQTLESAFK 15.21 519.76 581.29 28 257 DQTLESAFK 15.21 519.76 694.38 28 258 DQTLESAFK 15.21 519.76 795.42 28 259 DSIVWYSQELTR 19.61 748.87 896.45 38 260 DSIVWYSQELTR 19.61 748.87 1082.53 38 261 DSIVWYSQELTR 19.61 748.87 1181.59 38 262 DSIVWYSQQLTR 19.1 748.38 895.46 38 263 DSIVWYSQQLTR 19.11 748.38 1081.54 38 264 DSIVWYSQQLTR 19.1 748.38 1180.61 38 265 DSNLR 1.77 302.66 402.25 18 266 DSNLR 1.77 302.66 430.19 18 267 DSNLR 1.77 302.66 489.28 18 268 DSYIAWGGEAWK 19.67 691.82 833.39 35 269 DSYIAWGGEAWK 19.67 691.82 904.43 35 270 DSYIAWGGEAWK 19.66 691.82 1017.52 35 271 DTLNPEWPYK 17.3 631.81 819.4 33 272 DTLNPEWPYK 17.3 631.81 933.45 33 273 DTLNPEWPYK 17.3 631.81 1046.53 33 274 DVDEVFYK 15.62 507.74 685.36 27 275 DVDEVFYK 15.62 507.74 800.38 27 276 DVDEVFYK 15.62 507.74 899.45 27 277 DWILR 17.44 351.7 415.2 20 278 DWILR 17.44 351.7 528.28 20 279 DWILR 17.44 351.7 587.37 20 280 EAFLR 12.51 318.18 435.27 19 281 EAFLR 12.51 318.18 461.24 19 282 EAFLR 12.51 318.18 506.31 19 283 EAIVR 7.84 294.18 387.27 18 284 EAIVR 7.84 294.18 413.24 18 285 EAIVR 7.84 294.18 458.31 18 286 EAIVTEATPEYIVHSK 16.43 596.31 746.42 34 287 EAIVTEATPEYIVHSK 16.43 596.31 972.51 34 288 EAIVTEATPEYIVHSK 16.42 596.31 1073.56 34 289 EALVTEAAPEYLVHSK 17.3 586.31 875.46 33 290 EALVTEAAPEYLVHSK 17.3 586.31 972.51 33 291 EALVTEAAPEYLVHSK 17.3 586.31 1114.59 33 292 EALVTEAPEYLVHSK 17.58 562.63 637.32 32 293 EALVTEAPEYLVHSK 17.58 562.63 972.51 32 294 EALVTEAPEYLVHSK 17.58 562.63 1043.55 32 295 EEIVR 8.41 323.18 387.27 19 296 EEIVR 8.4 323.18 471.24 19 297 EEIVR 8.4 323.18 516.31 19 298 EEVLAALPAQLK 19.48 641.37 740.47 33 299 EEVLAALPAQLK 19.47 641.37 811.5 33 300 EEVLAALPAQLK 19.47 641.37 924.59 33 301 EFSAEAVNGVFVLC[CAM]K 21.1 835.42 936.5 42 302 EFSAEAVNGVFVLC[CAM]K 21.1 835.42 1106.6 42 303 EFSAEAVNGVFVLC[CAM]K 21.1 835.42 1235.65 42 304 EFSSESVHGVFVLC[CAM]K 18.26 575.62 666.36 33 305 EFSSESVHGVFVLC[CAM]K 18.26 575.62 822.45 33 306 EFSSESVHGVFVLC[CAM]K 18.26 575.62 959.51 33 307 EGMSGSIR 9.88 418.7 432.26 23 308 EGMSGSIR 9.88 418.7 519.29 23 309 EGMSGSIR 9.88 418.7 707.35 23 310 EGMTGSIR 10.63 425.71 432.26 24 311 EGMTGSIR 10.63 425.71 533.3 24 312 EGMTGSIR 10.63 425.71 664.34 24 313 EIAVWNR 14.78 444.24 475.24 25 314 EIAVWNR 14.77 444.24 574.31 25 315 EIAVWNR 14.77 444.24 645.35 25 316 EIAYK 8.46 312.17 381.21 19 317 EIAYK 8.46 312.17 477.23 19 318 EIAYK 8.46 312.17 494.3 19 319 EIFER 11.7 347.18 451.23 20 320 EIFER 11.7 347.18 519.24 20 321 EIFER 11.7 347.18 564.31 20 322 EIFYHYR 13.31 514.25 785.37 28 323 EIFYHYR 13.31 514.25 853.39 28 324 EIFYHYR 13.32 514.25 898.46 28 325 EIGDDK 1.99 338.66 434.19 20 326 EIGDDK 1.99 338.66 530.21 20 327 EIGDDK 1.99 338.66 547.27 20 328 EIGDGK 1.76 309.66 376.18 19 329 EIGDGK 1.75 309.66 472.2 19 330 EIGDGK 1.75 309.66 489.27 19 331 EIGEDK 2.32 345.67 448.2 20 332 EIGEDK 2.33 345.67 544.22 20 333 EIGEDK 2.33 345.67 561.29 20 334 EIGEDNAR 10.05 452.21 604.27 25 335 EIGEDNAR 10.05 452.21 661.29 25 336 EIGEDNAR 10.06 452.21 774.37 25 337 EIGENK 1.86 345.18 447.22 20 338 EIGENK 1.86 345.18 543.24 20 339 EIGENK 1.86 345.18 560.3 20 340 EIGSEIDK 11.04 445.73 591.3 25 341 EIGSEIDK 11.04 445.73 648.32 25 342 EIGSEIDK 11.04 445.73 761.4 25 343 EMIYLK 15.11 398.72 536.34 23 344 EMIYLK 15.11 398.72 650.32 23 345 EMIYLK 15.11 398.72 667.38 23 346 EMLYVER 14.12 470.23 566.29 26 347 EMLYVER 14.12 470.23 679.38 26 348 EMLYVER 14.12 470.23 810.42 26 349 ENIEK 11.07 316.67 389.24 19 350 ENIEK 11.07 316.67 486.22 19 351 ENIEK 11.07 316.67 503.28 19 352 ENQLIVK 12.15 422.25 472.35 24 353 ENQLIVK 12.15 422.25 600.41 24 354 ENQLIVK 12.15 422.25 714.45 24 355 EQAILLFR 19.88 495.29 548.36 27 356 EQAILLFR 19.88 495.29 661.44 27 357 EQAILLFR 19.88 495.29 732.48 27 358 EQIQFLLR 19.45 523.8 548.36 28 359 EQIQFLLR 19.45 523.8 676.41 28 360 EQIQFLLR 19.45 523.8 789.5 28 361 EQLAFDPQVQQQVK 16.43 829.43 954.54 41 362 EQLAFDPQVQQQVK 16.42 829.43 1069.56 41 363 EQLAFDPQVQQQVK 16.42 829.43 1216.63 41 364 EQVDFVQR 13.09 510.76 549.31 27 365 EQVDFVQR 13.09 510.76 664.34 27 366 EQVDFVQR 13.09 510.76 763.41 27 367 EVGEIR 9.35 351.69 474.27 20 368 EVGEIR 9.35 351.69 528.27 20 369 EVGEIR 9.35 351.69 573.34 20 370 EVGEVR 6.91 344.68 460.25 20 371 EVGEVR 6.91 344.68 514.25 20 372 EVGEVR 6.91 344.68 559.32 20 373 EYLPASTFK 15.41 528.27 553.3 28 374 EYLPASTFK 15.41 528.27 650.35 28 375 EYLPASTFK 15.41 528.27 763.43 28 376 EYLPVSTFK 17.16 542.29 581.33 29 377 EYLPVSTFK 17.16 542.29 678.38 29 378 EYLPVSTFK 17.16 542.29 791.47 29 379 EYNTSGTFVFYDGK 18.2 814.37 1033.5 41 380 EYNTSGTFVFYDGK 18.2 814.37 1120.53 41 381 EYNTSGTFVFYDGK 18.2 814.37 1221.58 41 382 EYVPASTFK 13.89 521.27 553.3 28 383 EYVPASTFK 13.89 521.27 650.35 28 384 EYVPASTFK 13.89 521.27 749.42 28 385 FAPESTFK 13.67 463.73 482.26 25 386 FAPESTFK 13.67 463.73 611.3 25 387 FAPESTFK 13.67 463.73 708.36 25 388 FAQYAK 9.39 364.19 509.27 21 389 FAQYAK 9.39 364.19 580.31 21 390 FAQYAK 9.39 364.19 581.27 21 391 FDYGNR 10.1 386.17 509.25 22 392 FDYGNR 10.1 386.17 597.23 22 393 FDYGNR 10.09 386.17 624.27 22 394 FEDLYK 13.52 407.7 423.26 23 395 FEDLYK 13.52 407.7 538.29 23 396 FEDLYK 13.52 407.7 667.33 23 397 FEDTFHISNQK 14.33 455.89 476.25 27 398 FEDTFHISNQK 14.33 455.89 589.33 27 399 FEDTFHISNQK 14.33 455.89 726.39 27 400 FEDTFHTSNQQHEK 10.66 583.26 870.41 33 401 FEDTFHTSNQQHEK 10.66 583.26 971.45 33 402 FEDTFHTSNQQHEK 10.66 583.26 1108.51 33 403 FEYGNQDVSGDSGK 11.95 751.82 764.34 38 404 FEYGNQDVSGDSGK 11.95 751.82 1063.47 38 405 FEYGNQDVSGDSGK 11.95 751.82 1226.53 38 406 FFSDFQAK 16 495.24 608.3 27 407 FFSDFQAK 16 495.24 695.34 27 408 FFSDFQAK 16 495.24 842.4 27 409 FFSDLQAEGAIVIADER 20.44 627.65 1143.6 35 410 FFSDLQAEGAIVIADER 20.43 940.97 1143.6 46 411 FFSDLQAEGAIVIADER 20.44 940.97 1179.57 46 412 FFSDLR 15.38 392.7 490.26 22 413 FFSDLR 15.38 392.7 610.29 22 414 FFSDLR 15.38 392.7 637.33 22 415 FFSEFQAK 16.13 502.25 622.32 27 416 FFSEFQAK 16.13 502.25 709.35 27 417 FFSEFQAK 16.13 502.25 856.42 27 418 FGLEGQLR 15.8 460.25 473.28 25 419 FGLEGQLR 15.8 460.25 602.33 25 420 FGLEGQLR 15.8 460.25 772.43 25 421 FLESLYLNNLPASK 20.75 804.94 856.49 40 422 FLESLYLNNLPASK 20.75 804.94 1019.55 40 423 FLESLYLNNLPASK 20.75 804.94 1219.67 40 424 FLLEGQLR 18.06 488.28 602.33 26 425 FLLEGQLR 18.06 488.28 715.41 26 426 FLLEGQLR 18.06 488.28 828.49 26 427 FQQYVDR 11.19 478.24 552.28 26 428 FQQYVDR 11.19 478.24 680.34 26 429 FQQYVDR 11.19 478.24 808.39 26 430 FSDYVQR 11.83 457.72 565.31 25 431 FSDYVQR 11.83 457.72 680.34 25 432 FSDYVQR 11.83 457.72 767.37 25 433 FSTASTFK 12.71 444.73 553.3 25 434 FSTASTFK 12.7 444.73 654.35 25 435 FSTASTFK 12.7 444.73 741.38 25 436 FSWDGK 14.32 370.17 505.24 21 437 FSWDGK 14.32 370.17 592.27 21 438 FSWDGK 14.32 370.17 593.24 21 439 FSYGNQNISGGIDK 14.61 750.36 803.43 38 440 FSYGNQNISGGIDK 14.61 750.36 1045.53 38 441 FSYGNQNISGGIDK 14.61 750.36 1102.55 38 442 FSYGNQNISGGTDK 12.74 744.34 791.39 38 443 FSYGNQNISGGTDK 12.74 744.34 1033.49 38 444 FSYGNQNISGGTDK 12.74 744.34 1090.51 38 445 FSYGSQNISGGIDK 14.74 736.85 803.43 37 446 FSYGSQNISGGIDK 14.74 736.85 1075.54 37 447 FSYGSQNISGGIDK 14.75 736.85 1238.6 37 448 FTEYVK 11.81 393.71 538.29 22 449 FTEYVK 11.81 393.71 639.33 22 450 FTEYVK 11.81 393.71 640.3 22 451 FVPASTYK 11.76 456.74 498.26 25 452 FVPASTYK 11.76 456.74 569.29 25 453 FVPASTYK 11.77 456.74 666.35 25 454 FVYDLAQGQLPFKPEVQQQVK 20.48 821.44 955.52 45 455 FVYDLAQGQLPFKPEVQQQVK 20.48 821.44 1108.59 45 456 FVYDLAQGQLPFKPEVQQQVK 20.49 821.44 1109.07 45 457 FWLEDQLR 20.39 553.79 660.33 29 458 FWLEDQLR 20.39 553.79 773.42 29 459 FWLEDQLR 20.38 553.79 959.49 29 460 FWLEGPLK 20.63 495.28 543.31 27 461 FWLEGPLK 20.63 495.28 656.4 27 462 FWLEGPLK 20.63 495.28 842.48 27 463 FWLEGQLR 19.49 524.78 602.33 28 464 FWLEGQLR 19.49 524.78 715.41 28 465 FWLEGQLR 19.48 524.78 901.49 28 466 FYPASSFK 14.74 473.74 636.34 26 467 FYPASSFK 14.74 473.74 799.4 26 468 FYPASSFK 14.74 473.74 800.36 26 469 FYPASTFK 14.98 480.74 553.3 26 470 FYPASTFK 14.99 480.74 650.35 26 471 FYPASTFK 14.98 480.74 813.41 26 472 GAIQVSAVPVFQQIAR 21.6 842.48 958.55 42 473 GAIQVSAVPVFQQIAR 21.6 842.48 1057.62 42 474 GAIQVSAVPVFQQIAR 21.59 842.48 1128.65 42 475 GAIQVSAVPVFQQITR 21.52 857.49 988.56 43 476 GAIQVSAVPVFQQITR 21.51 857.49 1087.63 43 477 GAIQVSAVPVFQQITR 21.52 857.49 1158.66 43 478 GELPVSEDALEMTK 18.1 759.87 936.43 38 479 GELPVSEDALEMTK 18.11 759.87 1023.47 38 480 GELPVSEDALEMTK 18.11 759.87 1122.53 38 481 GISSSVR 8.65 353.2 448.25 21 482 GISSSVR 8.65 353.2 535.28 21 483 GISSSVR 8.67 353.2 648.37 21 484 GNQTLVFAR 14.83 503.28 605.38 27 485 GNQTLVFAR 14.83 503.28 706.42 27 486 GNQTLVFAR 14.83 503.28 834.48 27 487 GPLEISAFEEAR 18.95 659.84 809.38 34 488 GPLEISAFEEAR 18.94 659.84 922.46 34 489 GPLEISAFEEAR 18.94 659.84 1051.51 34 490 GPLTITPIQEVK 18.14 648.38 814.47 34 491 GPLTITPIQEVK 18.15 648.38 927.55 34 492 GPLTITPIQEVK 18.14 648.38 1028.6 34 493 GSLLLWDQK 19.61 530.3 576.28 28 494 GSLLLWDQK 19.61 530.3 689.36 28 495 GSLLLWDQK 19.61 530.3 802.45 28 496 GTFVLYDVQR 17.93 599.32 680.34 31 497 GTFVLYDVQR 17.93 599.32 793.42 31 498 GTFVLYDVQR 17.93 599.32 892.49 31 499 GTIVVADER 11.82 480.26 490.23 26 500 GTIVVADER 11.82 480.26 589.29 26 501 GTIVVADER 11.82 480.26 688.36 26 502 GTIVVLDAR 15.77 472.28 573.34 26 503 GTIVVLDAR 15.77 472.28 672.4 26 504 GTIVVLDAR 15.77 472.28 785.49 26 505 GTIVVVDER 13.6 494.28 518.26 27 506 GTIVVVDER 13.6 494.28 617.33 27 507 GTIVVVDER 13.6 494.28 716.39 27 508 GTLPFSAR 14.96 424.73 577.31 24 509 GTLPFSAR 14.96 424.73 690.39 24 510 GTLPFSAR 14.97 424.73 791.44 24 511 HIADSK 11.91 335.68 420.21 20 512 HIADSK 11.9 335.68 524.25 20 513 HIADSK 11.91 335.68 533.29 20 514 HNGTDGAWIISSLR 19.36 509.6 575.35 29 515 HNGTDGAWIISSLR 19.35 509.6 653.26 29 516 HNGTDGAWIISSLR 19.36 509.6 688.44 29 517 HTLSVFDQER 14.25 411.21 432.22 25 518 HTLSVFDQER 14.25 411.21 547.25 25 519 HTLSVFDQER 14.25 411.21 694.32 25 520 HVTFASFR 14.36 322.17 338.18 20 521 HVTFASFR 14.36 322.17 409.22 20 522 HVTFASFR 14.36 322.17 485.25 20 523 IAISLMGYDAGFLR 23.93 763.91 898.44 39 524 IAISLMGYDAGFLR 23.93 763.91 1029.48 39 525 IAISLMGYDAGFLR 23.94 763.91 1229.6 39 526 IALSLMGFDSGILK 24.91 732.91 836.45 37 527 IALSLMGFDSGILK 24.91 732.91 967.49 37 528 IALSLMGFDSGILK 24.91 732.91 1167.61 37 529 IANALIGLENHK 15.95 431.58 697.36 26 530 IANALIGLENHK 15.95 646.87 697.36 33 531 IANALIGLENHK 15.95 646.87 810.45 33 532 IDTFWLDNSLK 21.79 676.35 689.38 35 533 IDTFWLDNSLK 21.79 676.35 875.46 35 534 IDTFWLDNSLK 21.79 676.35 1123.58 35 535 IDYYNLDR 14.85 536.26 680.34 29 536 IDYYNLDR 14.85 536.26 843.4 29 537 IDYYNLDR 14.85 536.26 958.43 29 538 IFNALIALDSGVIK 24.74 737.44 802.47 37 539 IFNALIALDSGVIK 24.74 737.44 915.55 37 540 IFNALIALDSGVIK 24.74 737.44 1028.64 37 541 IFNSLLALDSGALDNER 22.76 924.48 976.43 46 542 IFNSLLALDSGALDNER 22.77 924.48 1089.52 46 543 IFNSLLALDSGALDNER 22.76 924.48 1160.55 46 544 IFNTLIGLENGIVK 23.29 765.95 829.48 39 545 IFNTLIGLENGIVK 23.3 765.95 942.56 39 546 IFNTLIGLENGIVK 23.3 765.95 1055.65 39 547 IGLDLMQK 17.7 459.26 634.32 25 548 IGLDLMQK 17.7 459.26 747.41 25 549 IGLDLMQK 17.7 459.26 804.43 25 550 IGLEK 8.54 280.18 389.24 17 551 IGLEK 8.55 280.18 413.24 17 552 IGLEK 8.54 280.18 446.26 17 553 IGLELMQQEVQR 18.73 722.38 787.41 37 554 IGLELMQQEVQR 18.73 722.38 918.45 37 555 IGLELMQQEVQR 18.73 722.38 1031.53 37 556 IGLELMSK 17.52 445.75 478.27 25 557 IGLELMSK 17.52 445.75 720.4 25 558 IGLELMSK 17.52 445.75 777.42 25 559 IGLELMSNEVK 18.73 616.83 707.34 32 560 IGLELMSNEVK 18.73 616.83 820.42 32 561 IGLELMSNEVK 18.73 616.83 949.47 32 562 IGLER 10.96 294.18 304.16 18 563 IGLER 10.96 294.18 417.25 18 564 IGLER 10.96 294.18 474.27 18 565 IGLNK 9.59 272.68 374.24 17 566 IGLNK 9.59 272.68 398.24 17 567 IGLNK 9.59 272.68 431.26 17 568 IGLNLMQK 17.1 458.77 633.34 25 569 IGLNLMQK 17.09 458.77 746.42 25 570 IGLNLMQK 17.11 458.77 803.44 25 571 IGPSLMQSELQR 17.02 679.86 760.39 35 572 IGPSLMQSELQR 17.02 679.86 891.44 35 573 IGPSLMQSELQR 17.02 679.86 1188.6 35 574 IGYGNMQIGTEVDQFWLK 24.31 700.35 935.5 39 575 IGYGNMQIGTEVDQFWLK 24.32 1050.02 1164.54 51 576 IGYGNMQIGTEVDQFWLK 24.3 1050.02 1222.61 51 577 IINHNLPVK 11.88 349.88 456.32 21 578 IINHNLPVK 11.88 349.88 570.36 21 579 IINHNLPVK 11.88 349.88 592.32 21 580 IINHNLPVR 12.04 359.22 598.37 22 581 IINHNLPVR 12.04 538.32 598.37 29 582 IINHNLPVR 12.04 538.32 849.47 29 583 ILFQQGTQQAC[CAM]AER 14.51 550.61 606.27 32 584 ILFQQGTQQAC[CAM]AER 14.51 825.41 1020.45 41 585 ILFQQGTQQAC[CAM]AER 14.51 825.41 1148.51 41 586 ILNNWFK 18.98 467.76 594.3 26 587 ILNNWFK 18.98 467.76 708.35 26 588 ILNNWFK 18.97 467.76 821.43 26 589 ILNTLISLEEK 19.98 636.87 718.4 33 590 ILNTLISLEEK 19.98 636.87 1046.57 33 591 ILNTLISLEEK 19.98 636.87 1159.66 33 592 INIVK 11.43 293.7 359.27 18 593 INIVK 11.43 293.7 440.29 18 594 INIVK 11.43 293.7 473.31 18 595 INLYGNALSR 16.05 560.81 617.34 30 596 INLYGNALSR 16.05 560.81 780.4 30 597 INLYGNALSR 16.05 560.81 893.48 30 598 IPFSLNLEMK 21.68 596.33 834.44 31 599 IPFSLNLEMK 21.67 596.33 981.51 31 600 IPFSLNLEMK 21.67 596.33 1078.56 31 601 IPHTLFALDADAVR 20 513.62 531.29 30 602 IPHTLFALDADAVR 20 513.62 646.32 30 603 IPHTLFALDADAVR 20 769.92 1191.64 39 604 IPHTLFALDAGAAR 18.58 726.9 744.4 37 605 IPHTLFALDAGAAR 18.58 726.9 891.47 37 606 IPHTLFALDAGAAR 18.58 726.9 1004.55 37 607 IPHTLFALDAGAVR 19.72 494.28 588.31 29 608 IPHTLFALDAGAVR 19.71 494.28 780.44 29 609 IPHTLFALDAGAVR 19.72 740.92 1133.63 38 610 IPNAIIGLETGVIK 21.75 719.44 816.48 37 611 IPNAIIGLETGVIK 21.75 719.44 929.57 37 612 IPNAIIGLETGVIK 21.75 719.44 1227.73 37 613 IPNALIGLETGAIK 20.96 705.42 788.45 36 614 IPNALIGLETGAIK 20.96 705.42 901.54 36 615 IPNALIGLETGAIK 20.96 705.42 1014.62 36 616 IPNSLIAFDTGAVR 20.24 737.41 765.39 37 617 IPNSLIAFDTGAVR 20.24 737.41 836.43 37 618 IPNSLIAFDTGAVR 20.24 737.41 949.51 37 619 IPSAIIGLETGVIK 21.66 705.93 816.48 36 620 IPSAIIGLETGVIK 21.67 705.93 929.57 36 621 IPSAIIGLETGVIK 21.66 705.93 1200.72 36 622 ISAFNQVK 13.02 453.76 488.28 25 623 ISAFNQVK 13.02 453.76 706.39 25 624 ISAFNQVK 13.02 453.76 793.42 25 625 ISAHEQILFLR 18.28 442.92 548.36 26 626 ISAHEQILFLR 18.28 442.92 789.5 26 627 ISAHEQILFLR 18.28 663.88 918.54 34 628 ISAMEQTR 9.84 468.23 664.31 26 629 ISAMEQTR 9.84 468.23 735.35 26 630 ISAMEQTR 9.84 468.23 822.38 26 631 ISAMEQVK 11.65 453.24 634.32 25 632 ISAMEQVK 11.65 453.24 705.36 25 633 ISAMEQVK 11.65 453.24 792.39 25 634 ISATEQVAFLR 17.7 412.23 435.27 25 635 ISATEQVAFLR 17.71 412.23 506.31 25 636 ISATEQVAFLR 17.7 412.23 605.38 25 637 ISATQQIAFLR 18.58 624.36 747.45 32 638 ISATQQIAFLR 18.58 624.36 1047.59 32 639 ISATQQIAFLR 18.58 624.36 1134.63 32 640 ISAVNQVEFLESLFLNK 28.77 976.03 988.51 48 641 ISAVNQVEFLESLFLNK 28.77 976.03 1110.62 48 642 ISAVNQVEFLESLFLNK 28.77 976.03 1239.66 48 643 ISAVNQVK 10.32 429.76 488.28 24 644 ISAVNQVK 10.32 429.76 658.39 24 645 ISAVNQVK 10.32 429.76 745.42 24 646 ISPEEQIQFLR 18.87 680.37 933.52 35 647 ISPEEQIQFLR 18.87 680.37 1062.56 35 648 ISPEEQIQFLR 18.87 680.37 1159.61 35 649 ISPEEQVR 10.49 479.25 531.29 26 650 ISPEEQVR 10.49 479.25 660.33 26 651 ISPEEQVR 10.49 479.25 757.38 26 652 ISPEGQVR 9.86 443.24 459.27 25 653 ISPEGQVR 9.86 443.24 588.31 25 654 ISPEGQVR 9.86 443.24 685.36 25 655 ISPLEQLAFLR 24.02 643.88 876.49 33 656 ISPLEQLAFLR 24.01 643.88 989.58 33 657 ISPLEQLAFLR 24.02 643.88 1086.63 33 658 ITAFQQVDFLR 21.11 669.36 777.43 34 659 ITAFQQVDFLR 21.12 669.36 905.48 34 660 ITAFQQVDFLR 21.12 669.36 1123.59 34 661 ITPIQEVNFADDFANNR 21.25 655.32 736.34 37 662 ITPIQEVNFADDFANNR 21.25 655.32 851.36 37 663 ITPIQEVNFADDFANNR 21.25 655.32 922.4 37 664 ITPIQEVNFADDLANNR 20.95 643.99 817.38 36 665 ITPIQEVNFADDLANNR 20.95 965.49 1149.53 47 666 ITPIQEVNFADDLANNR 20.96 965.49 1248.6 47 667 ITPQQEAQFAYK 14.52 712.36 856.42 36 668 ITPQQEAQFAYK 14.52 712.36 984.48 36 669 ITPQQEAQFAYK 14.52 712.36 1209.59 36 670 ITPQQEAQFTYK 14.33 485.25 558.29 28 671 ITPQQEAQFTYK 14.33 727.37 1014.49 37 672 ITPQQEAQFTYK 14.33 727.37 1239.6 37 673 ITPVQEVNFADDLAHNR 18.98 646.99 840.4 36 674 ITPVQEVNFADDLAHNR 18.98 646.99 862.92 36 675 ITPVQEVNFADDLAHNR 18.98 646.99 911.43 36 676 IVAFALK 17.21 381.25 478.3 22 677 IVAFALK 17.22 381.25 549.34 22 678 IVAFALK 17.21 381.25 648.41 22 679 IVAFALNMEMR 17.95 647.84 864.41 34 680 IVAFALNMEMR 17.95 647.84 1011.48 34 681 IVAFALNMEMR 17.97 647.84 1082.51 34 682 IVESTTLADGTWHGK 13.69 542.96 697.4 31 683 IVESTTLADGTWHGK 13.69 542.96 812.43 31 684 IVESTTLADGTWHGK 13.68 542.96 883.46 31 685 IYNSLIGLNEK 17.37 632.35 673.39 33 686 IYNSLIGLNEK 17.37 632.35 786.47 33 687 IYNSLIGLNEK 17.37 632.35 987.55 33 688 KPDIGVVWVGWIER 24.47 547.96 660.35 31 689 KPDIGVVWVGWIER 24.47 547.96 883.45 31 690 KPDIGVVWVGWIER 24.46 821.43 1188.59 41 691 LAC[CAM]ATNNLAR 11.22 552.28 688.37 29 692 LAC[CAM]ATNNLAR 11.22 552.28 759.41 29 693 LAC[CAM]ATNNLAR 11.22 552.28 919.44 29 694 LAQGELPFPAPVQSTVR 19.84 905.5 954.54 45 695 LAQGELPFPAPVQSTVR 19.84 905.5 1101.61 45 696 LAQGELPFPAPVQSTVR 19.84 905.5 1198.66 45 697 LAQNELPYPIEIQK 19.09 828.45 929.47 41 698 LAQNELPYPIEIQK 19.09 828.45 987.55 41 699 LAQNELPYPIEIQK 19.08 828.45 1100.64 41 700 LAQNELQYPIEIQK 17.98 843.96 890.5 42 701 LAQNELQYPIEIQK 17.98 843.96 1018.56 42 702 LAQNELQYPIEIQK 17.98 843.96 1131.64 42 703 LDFGNK 11.75 347.18 465.25 20 704 LDFGNK 11.74 347.18 547.25 20 705 LDFGNK 11.75 347.18 580.27 20 706 LDGSLNR 9.48 387.71 402.25 22 707 LDGSLNR 9.48 387.71 546.3 22 708 LDGSLNR 9.48 387.71 661.33 22 709 LEILQQALAELGLYPK 29.81 900.02 1003.58 45 710 LEILQQALAELGLYPK 29.81 900.02 1074.62 45 711 LEILQQALAELGLYPK 29.81 900.02 1202.68 45 712 LENQEQVK 7.6 494.26 631.34 27 713 LENQEQVK 7.59 494.26 745.38 27 714 LENQEQVK 7.59 494.26 874.43 27 715 LETQEEVEK 9.88 552.77 633.31 29 716 LETQEEVEK 9.88 552.77 862.42 29 717 LETQEEVEK 9.88 552.77 991.46 29 718 LETQEEVK 9.5 488.25 504.27 26 719 LETQEEVK 9.49 488.25 733.37 26 720 LETQEEVK 9.49 488.25 862.42 26 721 LFAAEGVK 13.53 417.74 503.28 23 722 LFAAEGVK 13.53 417.74 574.32 23 723 LFAAEGVK 13.53 417.74 721.39 23 724 LFESAGVK 12.99 425.74 461.27 24 725 LFESAGVK 12.99 425.74 590.31 24 726 LFESAGVK 12.99 425.74 737.38 24 727 LFGAAGVK 13.94 381.73 445.28 22 728 LFGAAGVK 13.94 381.73 502.3 22 729 LFGAAGVK 13.94 381.73 649.37 22 730 LGVDR 8.51 280.16 290.15 17 731 LGVDR 8.51 280.16 389.21 17 732 LGVDR 8.5 280.16 446.24 17 733 LLNLLSQSK 17.97 508.31 562.32 27 734 LLNLLSQSK 17.97 508.31 789.45 27 735 LLNLLSQSK 17.97 508.31 902.53 27 736 LLQDER 9.34 387.21 547.25 22 737 LLQDER 9.31 387.21 599.3 22 738 LLQDER 9.34 387.21 660.33 22 739 LLVQDGDC[CAM]GR 11.92 566.77 679.25 30 740 LLVQDGDC[CAM]GR 11.92 566.77 807.3 30 741 LLVQDGDC[CAM]GR 11.92 566.77 906.37 30 742 LNEVGYGNR 10.74 511.26 566.27 27 743 LNEVGYGNR 10.74 511.26 665.34 27 744 LNEVGYGNR 10.73 511.26 794.38 27 745 LNYGNADPSTK 10.76 590.29 732.35 31 746 LNYGNADPSTK 10.76 590.29 789.37 31 747 LNYGNADPSTK 10.76 590.29 952.44 31 748 LNYGNK 7.21 354.69 481.24 21 749 LNYGNK 7.24 354.69 562.26 21 750 LNYGNK 7.22 354.69 595.28 21 751 LPASK 1.93 258.16 305.18 16 752 LPASK 1.93 258.16 369.21 16 753 LPASK 1.93 258.16 402.23 16 754 LPHTLFALDADAVR 19.98 769.92 977.51 39 755 LPHTLFALDADAVR 19.98 769.92 1090.59 39 756 LPHTLFALDADAVR 19.98 769.92 1191.64 39 757 LPHTLFALDAGAVR 19.7 740.92 919.5 38 758 LPHTLFALDAGAVR 19.67 740.92 1032.58 38 759 LPHTLFALDAGAVR 19.7 740.92 1133.63 38 760 LPLAIMGFDSGILQSPK 25.08 893.99 944.5 44 761 LPLAIMGFDSGILQSPK 25.08 893.99 1091.57 44 762 LPLAIMGFDSGILQSPK 25.08 893.99 1148.59 44 763 LPLAIMGYDADILLDATTPR 27.86 720.39 773.42 40 764 LPLAIMGYDADILLDATTPR 27.87 720.39 886.5 40 765 LPLAIMGYDADILLDATTPR 27.87 720.39 1160.57 40 766 LPSSLIALETGAVR 20.6 713.92 816.46 36 767 LPSSLIALETGAVR 20.6 713.92 929.54 36 768 LPSSLIALETGAVR 20.6 713.92 1216.69 36 769 LPVSAQTLQYTANILK 21.84 880.5 950.53 44 770 LPVSAQTLQYTANILK 21.84 880.5 1063.61 44 771 LPVSAQTLQYTANILK 21.85 880.5 1164.66 44 772 LPVSER 9.57 350.7 490.26 20 773 LPVSER 9.57 350.7 526.29 20 774 LPVSER 9.57 350.7 587.31 20 775 LPVSPTAVDMTER 16.21 708.36 1019.48 36 776 LPVSPTAVDMTER 16.21 708.36 1106.51 36 777 LPVSPTAVDMTER 16.21 708.36 1205.58 36 778 LSASK 10.72 253.15 305.18 16 779 LSASK 10.71 253.15 359.19 16 780 LSASK 10.71 253.15 392.21 16 781 LSAVPIYQEVAR 17.96 673.38 765.39 35 782 LSAVPIYQEVAR 17.96 673.38 975.53 35 783 LSAVPIYQEVAR 17.95 673.38 1074.59 35 784 LSAVPVYQELAR 18.45 449.25 616.34 26 785 LSAVPVYQELAR 18.44 673.38 779.4 35 786 LSAVPVYQELAR 18.44 673.38 975.53 35 787 LSC[CAM]TLVIDEASGDLLHR 20.38 633.66 797.43 36 788 LSC[CAM]TLVIDEASGDLLHR 20.38 633.66 868.46 36 789 LSC[CAM]TLVIDEASGDLLHR 20.38 633.66 1112.53 36 790 LSLQHGWFIGWIEK 23.95 571.98 632.34 33 791 LSLQHGWFIGWIEK 23.95 571.98 892.49 33 792 LSLQHGWFIGWIEK 23.95 571.98 969.49 33 793 LSQNSLPFSQEAMNSVK 18.64 627.31 1140.54 35 794 LSQNSLPFSQEAMNSVK 18.63 940.46 1140.54 46 795 LSQNSLPFSQEAMNSVK 18.64 940.46 1237.59 46 796 LSVNPK 9.8 329.2 457.28 19 797 LSVNPK 9.79 329.2 511.29 19 798 LSVNPK 9.8 329.2 544.31 19 799 LTVGAR 9.51 308.69 402.25 19 800 LTVGAR 9.51 308.69 442.27 19 801 LTVGAR 9.51 308.69 503.29 19 802 LYGFALNIDMPGGEADIGK 23.35 661 843.42 37 803 LYGFALNIDMPGGEADIGK 23.35 990.99 1089.49 49 804 LYGFALNIDMPGGEADIGK 23.35 990.99 1202.57 49 805 LYHNELPFR 15.29 396.88 414.21 24 806 LYHNELPFR 15.29 396.88 419.24 24 807 LYHNELPFR 15.29 396.88 657.3 24 808 LYHNK 8.54 337.68 414.21 20 809 LYHNK 8.53 337.68 528.26 20 810 LYHNK 8.53 337.68 561.28 20 811 LYQNDLPFR 17.2 583.3 761.39 31 812 LYQNDLPFR 17.2 583.3 889.45 31 813 LYQNDLPFR 17.2 583.3 1052.52 31 814 MDDLFK 15.5 384.68 522.29 22 815 MDDLFK 15.5 384.68 622.25 22 816 MDDLFK 15.5 384.68 637.32 22 817 MEDLHK 6.66 386.69 512.28 22 818 MEDLHK 6.65 386.69 626.26 22 819 MEDLHK 6.66 386.69 641.33 22 820 MLIALIGLENHK 21.33 451.26 527.26 27 821 MLIALIGLENHK 21.33 451.26 697.36 27 822 MLIALIGLENHK 21.33 451.26 810.45 27 823 MLLIK 15.81 309.21 373.28 19 824 MLLIK 15.81 309.21 471.3 19 825 MLLIK 15.81 309.21 486.36 19 826 MLNALIGLEHHK 16.89 459.26 550.27 27 827 MLNALIGLEHHK 16.89 459.26 720.38 27 828 MLNALIGLEHHK 16.89 459.26 833.46 27 829 MLNALIGLENHK 18.39 451.58 697.36 27 830 MLNALIGLENHK 18.38 676.87 697.36 35 831 MLNALIGLENHK 18.39 676.87 810.45 35 832 MLNALIGLENQK 19.71 672.37 688.36 35 833 MLNALIGLENQK 19.71 672.37 801.45 35 834 MLNALIGLENQK 19.71 672.37 914.53 35 835 MLNALIGLEYHK 19.6 701.38 746.38 36 836 MLNALIGLEYHK 19.6 701.38 859.47 36 837 MLNALIGLEYHK 19.6 701.38 1157.63 36 838 MLNALIGLQHGK 17.5 432.25 582.34 26 839 MLNALIGLQHGK 17.5 432.25 639.36 26 840 MLNALIGLQHGK 17.5 432.25 752.44 26 841 MLNALISLEHHK 17.2 352.2 359.17 21 842 MLNALISLEHHK 17.21 469.26 750.39 27 843 MLNALISLEHHK 17.2 469.26 863.47 27 844 MQAYVDAFDYGNR 17.56 775.34 957.41 39 845 MQAYVDAFDYGNR 17.56 775.34 1056.47 39 846 MQAYVDAFDYGNR 17.56 775.34 1219.54 39 847 MQEGLNK 8.68 410.21 560.3 23 848 MQEGLNK 8.66 410.21 673.3 23 849 MQEGLNK 8.68 410.21 688.36 23 850 MSPASTYK 9.49 442.71 569.29 24 851 MSPASTYK 9.49 442.71 666.35 24 852 MSPASTYK 9.49 442.71 753.38 24 853 NEHDPVLPYR 13.09 413.88 435.24 25 854 NEHDPVLPYR 13.09 620.31 744.44 32 855 NEHDPVLPYR 13.09 620.31 859.47 32 856 NEHQIFK 9.91 458.24 509.21 25 857 NEHQIFK 9.91 458.24 622.29 25 858 NEHQIFK 9.91 458.24 672.38 25 859 NEHQVFK 7.74 451.23 658.37 25 860 NEHQVFK 7.74 451.23 755.35 25 861 NEHQVFK 7.74 451.23 787.41 25 862 NEITYK 9.35 384.2 524.31 22 863 NEITYK 9.35 384.2 621.29 22 864 NEITYK 9.35 384.2 653.35 22 865 NELLMK 13.08 374.21 504.32 21 866 NELLMK 13.09 374.21 601.3 21 867 NELLMK 13.09 374.21 633.36 21 868 NELPFR 14.39 388.21 419.24 22 869 NELPFR 14.39 388.21 532.32 22 870 NELPFR 14.4 388.21 661.37 22 871 NISSYGNNLVR 14.36 618.82 835.44 32 872 NISSYGNNLVR 14.36 618.82 922.47 32 873 NISSYGNNLVR 14.36 618.82 1009.51 32 874 NISTYGNNLTR 13.1 626.82 674.36 33 875 NISTYGNNLTR 13.09 626.82 837.42 33 876 NISTYGNNLTR 13.1 626.82 1025.5 33 877 NLFNEVHTTGVLVIR 20.69 571.32 757.49 33 878 NLFNEVHTTGVLVIR 20.7 571.32 858.54 33 879 NLFNEVHTTGVLVIR 20.7 571.32 995.6 33 880 NLSTYGNALAR 14.34 590.31 764.4 31 881 NLSTYGNALAR 14.35 590.31 865.45 31 882 NLSTYGNALAR 14.35 590.31 952.48 31 883 NMENLELFGK 19.08 597.79 820.46 31 884 NMENLELFGK 19.08 597.79 949.5 31 885 NMENLELFGK 19.08 597.79 1080.54 31 886 NMLLLEENNGYK 16.71 719.36 853.37 37 887 NMLLLEENNGYK 16.69 719.36 966.45 37 888 NMLLLEENNGYK 16.68 719.36 1079.54 37 889 NMLLLEESNGYK 18.12 705.85 939.44 36 890 NMLLLEESNGYK 18.13 705.85 1052.53 36 891 NMLLLEESNGYK 18.11 705.85 1165.61 36 892 NMLLLEK 16.99 430.75 502.32 24 893 NMLLLEK 16.98 430.75 615.41 24 894 NMLLLEK 16.98 430.75 746.45 24 895 NMTLGDAMK 14.42 490.73 521.24 27 896 NMTLGDAMK 14.42 490.73 634.32 27 897 NMTLGDAMK 14.42 490.73 735.37 27 898 NNGLTEAWLESSLK 20.61 781.4 862.47 39 899 NNGLTEAWLESSLK 20.6 781.4 933.5 39 900 NNGLTEAWLESSLK 20.62 781.4 1163.59 39 901 NQLPFK 13.49 373.71 391.23 21 902 NQLPFK 13.49 373.71 504.32 21 903 NQLPFK 13.49 373.71 632.38 21 904 NQLPFQVEHQR 14.33 698.36 796.41 36 905 NQLPFQVEHQR 14.33 698.36 1040.53 36 906 NQLPFQVEHQR 14.33 698.36 1153.61 36 907 NSAIENTIDNMYLQDLENSTK 22.77 805.04 934.45 44 908 NSAIENTIDNMYLQDLENSTK 22.77 805.04 1047.53 44 909 NSAIENTIDNMYLQDLENSTK 22.77 805.04 1210.6 44 910 NSAIENTIENMYLQDLDNSTK 23.13 805.04 920.43 44 911 NSAIENTIENMYLQDLDNSTK 23.13 805.04 1033.52 44 912 NSAIENTIENMYLQDLDNSTK 23.14 805.04 1196.58 44 913 NSAIENTIENMYLQDLENSTK 23.7 809.72 934.45 44 914 NSAIENTIENMYLQDLENSTK 23.7 809.72 1047.53 44 915 NSAIENTIENMYLQDLENSTK 23.7 809.72 1217.55 44 916 NSAVWVYELFAK 24.66 713.87 869.48 36 917 NSAVWVYELFAK 24.66 713.87 1055.56 36 918 NSAVWVYELFAK 24.65 713.87 1154.62 36 919 NSQVPAYK 9.78 453.74 478.27 25 920 NSQVPAYK 9.78 453.74 577.33 25 921 NSQVPAYK 9.78 453.74 705.39 25 922 NSTVWIYELFAK 25.64 735.88 883.49 37 923 NSTVWIYELFAK 25.64 735.88 1069.57 37 924 NSTVWIYELFAK 25.64 735.88 1168.64 37 925 NSTVWVYELFAK 24.42 728.88 770.41 37 926 NSTVWVYELFAK 24.43 728.88 869.48 37 927 NSTVWVYELFAK 24.42 728.88 1055.56 37 928 NSTVWVYQLFAK 23.9 728.39 769.42 37 929 NSTVWVYQLFAK 23.91 728.39 1054.57 37 930 NSTVWVYQLFAK 23.91 728.39 1153.64 37 931 NTSGALVIQTDK 13.34 623.84 816.48 32 932 NTSGALVIQTDK 13.34 623.84 944.54 32 933 NTSGALVIQTDK 13.34 623.84 1031.57 32 934 NTSGVLVIQTDK 14.9 637.85 816.48 33 935 NTSGVLVIQTDK 14.9 637.85 972.57 33 936 NTSGVLVIQTDK 14.91 637.85 1059.6 33 937 NVDEMFYYYDGSK 18.86 815.84 895.38 41 938 NVDEMFYYYDGSK 18.86 815.84 1042.45 41 939 NVDEMFYYYDGSK 18.85 815.84 1173.49 41 940 NWILR 16.3 351.21 414.21 20 941 NWILR 16.29 351.21 527.3 20 942 NWILR 16.3 351.21 587.37 20 943 NWNAAMDLR 16.54 545.76 605.31 29 944 NWNAAMDLR 16.55 545.76 676.34 29 945 NWNAAMDLR 16.54 545.76 790.39 29 946 NYVDAFHYGNQDISGDK 15.76 648.29 933.43 36 947 NYVDAFHYGNQDISGDK 15.77 648.29 1096.49 36 948 NYVDAFHYGNQDISGDK 15.76 971.93 1233.55 48 949 QADHAILVFDQAR 16.58 495.26 523.23 29 950 QADHAILVFDQAR 16.61 495.26 636.31 29 951 QADHAILVFDQAR 16.58 495.26 735.38 29 952 QAEHALLVFGQER 16.86 499.93 636.31 29 953 QAEHALLVFGQER 16.85 499.93 735.38 29 954 QAEHALLVFGQER 16.87 499.93 763.41 29 955 QAITK 11 280.67 361.24 17 956 QAITK 11 280.67 414.23 17 957 QAITK 11.01 280.67 432.28 17 958 QAMLTEANSDYIIR 18.26 812.9 951.49 41 959 QAMLTEANSDYIIR 18.25 812.9 1080.53 41 960 QAMLTEANSDYIIR 18.26 812.9 1181.58 41 961 QEVQFVSALAR 17.69 624.34 763.45 32 962 QEVQFVSALAR 17.68 624.34 891.5 32 963 QEVQFVSALAR 17.68 624.34 990.57 32 964 QFASIK 11.66 347.2 434.2 20 965 QFASIK 11.66 347.2 547.29 20 966 QFASIK 11.68 347.2 565.33 20 967 QGMPGSIR 11.4 423.22 529.31 24 968 QGMPGSIR 11.43 423.22 660.35 24 969 QGMPGSIR 11.4 423.22 717.37 24 970 QGMSGSIR 9.44 418.21 519.29 23 971 QGMSGSIR 9.45 418.21 650.33 23 972 QGMSGSIR 9.44 418.21 707.35 23 973 QGQTQQSYGNDLAR 11.16 783.37 895.43 39 974 QGQTQQSYGNDLAR 11.17 783.37 1023.49 39 975 QGQTQQSYGNDLAR 11.16 783.37 1151.54 39 976 QIDYGNADPSTIK 13.41 711.35 845.44 36 977 QIDYGNADPSTIK 13.42 711.35 902.46 36 978 QIDYGNADPSTIK 13.42 711.35 1065.52 36 979 QIDYGNVDPSTIK 15.08 725.36 873.47 37 980 QIDYGNVDPSTIK 15.07 725.36 930.49 37 981 QIDYGNVDPSTIK 15.07 725.36 1093.55 37 982 QIGQAR 2.3 336.69 431.24 20 983 QIGQAR 2.33 336.69 498.27 20 984 QIGQAR 2.32 336.69 544.32 20 985 QIMLIEQTPAFTLR 24.42 830.96 933.52 42 986 QIMLIEQTPAFTLR 24.42 830.96 1062.56 42 987 QIMLIEQTPAFTLR 24.42 830.96 1175.64 42 988 QLGSAIDQFWLR 22.67 717.38 864.44 37 989 QLGSAIDQFWLR 22.68 717.38 977.52 37 990 QLGSAIDQFWLR 22.67 717.38 1192.61 37 991 QLPVK 9.57 292.69 343.23 18 992 QLPVK 9.58 292.69 438.27 18 993 QLPVK 9.57 292.69 456.32 18 994 QLSLDVLDK 18.63 515.79 589.32 28 995 QLSLDVLDK 18.62 515.79 789.44 28 996 QLSLDVLDK 18.63 515.79 902.52 28 997 QLVYAR 11.04 375.22 508.29 22 998 QLVYAR 11.04 375.22 575.32 22 999 QLVYAR 11.04 375.22 621.37 22 1000 QMMLTEASTDYIIR 19.82 836.41 867.46 42 1001 QMMLTEASTDYIIR 19.82 836.41 1067.54 42 1002 QMMLTEASTDYIIR 19.82 836.41 1168.58 42 1003 QMSIVEATPDYVLHGK 18.77 894.45 1029.54 44 1004 QMSIVEATPDYVLHGK 18.77 894.45 1100.57 44 1005 QMSIVEATPDYVLHGK 18.77 894.45 1229.62 44 1006 QTLVFAR 14.65 417.75 492.29 23 1007 QTLVFAR 14.65 417.75 605.38 23 1008 QTLVFAR 14.65 417.75 706.42 23 1009 QVVFAR 12.06 360.21 492.29 21 1010 QVVFAR 12.04 360.21 545.31 21 1011 QVVFAR 12.06 360.21 591.36 21 1012 SADEVLPYGGKPQR 12.96 506.26 642.37 29 1013 SADEVLPYGGKPQR 12.96 506.26 805.43 29 1014 SADEVLPYGGKPQR 12.96 506.26 902.48 29 1015 SC[CAM]ATNDLAR 9.37 504.23 689.36 27 1016 SC[CAM]ATNDLAR 9.37 504.23 760.39 27 1017 SC[CAM]ATNDLAR 9.37 504.23 920.43 27 1018 SC[CAM]ATNNLAR 8.66 503.74 688.37 27 1019 SC[CAM]ATNNLAR 8.66 503.74 759.41 27 1020 SC[CAM]ATNNLAR 8.67 503.74 919.44 27 1021 SDIPGGSK 7.63 380.7 558.32 22 1022 SDIPGGSK 7.63 380.7 614.28 22 1023 SDIPGGSK 7.63 380.7 673.35 22 1024 SDWGK 5.75 296.64 390.21 18 1025 SDWGK 5.75 296.64 446.17 18 1026 SDWGK 5.75 296.64 505.24 18 1027 SEDNFHISSQQHEK 10.36 422.19 541.27 24 1028 SEDNFHISSQQHEK 10.36 422.19 730.28 24 1029 SEDNFHISSQQHEK 10.36 422.19 756.36 24 1030 SEMPASIR 12.02 445.72 674.37 25 1031 SEMPASIR 12.02 445.72 716.33 25 1032 SEMPASIR 12.02 445.72 803.41 25 1033 SEMPASIR 8.2 439.71 662.33 24 1034 SEMPASTR 8.19 439.71 704.29 24 1035 SEMPASTR 8.19 439.71 791.37 24 1036 SFAAHNQDQDLR 10.35 467.89 531.29 27 1037 SFAAHNQDQDLR 10.35 467.89 871.37 27 1038 SFAAHNQDQDLR 10.35 467.89 888.42 27 1039 SFAGHNK 9.4 380.69 455.24 22 1040 SFAGHNK 9.4 380.69 526.27 22 1041 SFAGHNK 9.38 380.69 673.34 22 1042 SFAGHNQDQDLR 10.18 694.32 888.42 36 1043 SFAGHNQDQDLR 10.18 694.32 1025.48 36 1044 SFAGHNQDQDLR 10.18 694.32 1082.5 36 1045 SFAGHNQDQNLR 9.8 462.89 530.3 27 1046 SFAGHNQDQNLR 9.8 462.89 773.39 27 1047 SFAGHNQDQNLR 9.8 462.89 887.43 27 1048 SFLESWAK 18.27 484.25 491.26 26 1049 SFLESWAK 18.27 484.25 620.3 26 1050 SFLESWAK 18.27 484.25 733.39 26 1051 SFTAWEK 14.44 434.71 462.23 24 1052 SFTAWEK 14.44 434.71 533.27 24 1053 SFTAWEK 14.44 434.71 634.32 24 1054 SFTTWEK 14.1 449.72 462.23 25 1055 SFTTWEK 14.1 449.72 563.28 25 1056 SFTTWEK 14.1 449.72 664.33 25 1057 SGSGWLR 13.25 381.7 531.3 22 1058 SGSGWLR 13.25 381.7 618.34 22 1059 SGSGWLR 13.25 381.7 675.36 22 1060 SGWGMAVDPQVGWYVGFVEK 24.65 738.02 841.45 41 1061 SGWGMAVDPQVGWYVGFVEK 24.65 738.02 1029.45 41 1062 SGWGMAVDPQVGWYVGFVEK 24.68 1106.53 1128.51 54 1063 SGWGMDVSPQVGWLTGWVEK 26.32 1110.03 1144.51 54 1064 SGWGMDVSPQVGWLTGWVEK 26.32 1110.03 1174.63 54 1065 SGWGMDVSPQVGWLTGWVEK 26.32 1110.03 1201.53 54 1066 SGWGMDVTPQVGWLTGWVEK 26.61 745.03 832.46 41 1067 SGWGMDVTPQVGWLTGWVEK 26.61 745.03 1018.54 41 1068 SGWGMDVTPQVGWLTGWVEK 26.61 745.03 1075.56 41 1069 SIHPASTFK 10.74 494.27 650.35 27 1070 SIHPASTFK 10.73 494.27 787.41 27 1071 SIHPASTFK 10.73 494.27 900.49 27 1072 SISTK 10.41 268.16 335.19 17 1073 SISTK 10.42 268.16 389.2 17 1074 SISTK 10.42 268.16 448.28 17 1075 SLGLSNNLSR 14.23 530.79 690.35 28 1076 SLGLSNNLSR 14.23 530.79 803.44 28 1077 SLGLSNNLSR 14.23 530.79 860.46 28 1078 SLSMSGK 9.31 355.18 509.24 21 1079 SLSMSGK 9.32 355.18 563.25 21 1080 SLSMSGK 9.32 355.18 622.32 21 1081 SMLFIEEK 17.82 498.76 518.28 27 1082 SMLFIEEK 17.82 498.76 665.35 27 1083 SMLFIEEK 17.82 498.76 778.43 27 1084 SNGLTHSWLGSSLK 16.78 743.89 877.48 38 1085 SNGLTHSWLGSSLK 16.78 743.89 1014.54 38 1086 SNGLTHSWLGSSLK 16.78 743.89 1115.58 38 1087 SPTWELKPEYNPSPR 16.02 600.97 733.36 34 1088 SPTWELKPEYNPSPR 16.02 600.97 808.91 34 1089 SPTWELKPEYNPSPR 16.02 600.97 959.46 34 1090 SQDIVR 8.4 359.2 502.3 21 1091 SQDIVR 8.38 359.2 543.28 21 1092 SQDIVR 8.4 359.2 630.36 21 1093 SQQKPTDPTIWLK 16.6 514.62 660.41 30 1094 SQQKPTDPTIWLK 16.6 514.62 757.46 30 1095 SQQKPTDPTIWLK 16.6 514.62 785.38 30 1096 SQVGWLTGWVEQPDGK 22.27 893.94 1015.5 44 1097 SQVGWLTGWVEQPDGK 22.28 893.94 1116.53 44 1098 SQVGWLTGWVEQPDGK 22.28 893.94 1229.62 44 1099 SSSNSC[CAM]TTNNAAR 16.84 685.29 907.41 35 1100 SSSNSC[CAM]TTNNAAR 16.85 685.29 994.44 35 1101 SSSNSC[CAM]TTNNAAR 16.84 685.29 1108.48 35 1102 SVYGELR 12.65 412.22 417.25 23 1103 SVYGELR 12.65 412.22 474.27 23 1104 SVYGELR 12.65 412.22 637.33 23 1105 SWILR 16.33 337.7 401.29 20 1106 SWILR 16.32 337.7 500.29 20 1107 SWILR 16.33 337.7 587.37 20 1108 SYLEK 9.09 320.17 389.24 19 1109 SYLEK 9.09 320.17 493.23 19 1110 SYLEK 9.1 320.17 552.3 19 1111 TAYIPASTFK 15.43 549.8 650.35 29 1112 TAYIPASTFK 15.43 549.8 763.43 29 1113 TAYIPASTFK 15.43 549.8 926.5 29 1114 TDDLFK 13.48 369.69 407.27 21 1115 TDDLFK 13.48 369.69 522.29 21 1116 TDDLFK 13.48 369.69 637.32 21 1117 TDINEIFK 17.44 490.26 650.35 27 1118 TDINEIFK 17.44 490.26 763.43 27 1119 TDINEIFK 17.44 490.26 878.46 27 1120 TFIHNDPR 18.92 500.25 751.38 27 1121 TFIHNDPR 18.92 500.25 825.39 27 1122 TFIHNDPR 18.92 500.25 898.45 27 1123 TGAGFTANR 9.64 447.72 461.25 25 1124 TGAGFTANR 9.64 447.72 665.34 25 1125 TGAGFTANR 9.64 447.72 793.4 25 1126 TGFNDGQK 7.5 433.7 561.26 24 1127 TGFNDGQK 7.5 433.7 708.33 24 1128 TGFNDGQK 7.5 433.7 765.35 24 1129 TGLADSK 9.7 346.18 533.29 20 1130 TGLADSK 9.67 346.18 545.26 20 1131 TGLADSK 9.7 346.18 590.31 20 1132 TGLDLMQK 15.32 453.24 634.32 25 1133 TGLDLMQK 15.32 453.24 747.41 25 1134 TGLDLMQK 15.32 453.24 804.43 25 1135 TGLELMQK 15.03 460.25 648.34 25 1136 TGLELMQK 15.03 460.25 761.42 25 1137 TGLELMQK 15.03 460.25 818.44 25 1138 TGMGYPK 10.28 377.18 464.25 22 1139 TGMGYPK 10.28 377.18 595.29 22 1140 TGMGYPK 10.28 377.18 652.31 22 1141 TGNGR 0.8 252.63 330.14 16 1142 TGNGR 0.8 252.63 346.18 16 1143 TGNGR 0.81 252.63 403.2 16 1144 TGTGSFIDAR 13.35 512.76 708.37 28 1145 TGTGSFIDAR 13.35 512.76 765.39 28 1146 TGTGSFIDAR 13.35 512.76 866.44 28 1147 TGTGSLSDAK 8.32 468.74 620.32 26 1148 TGTGSLSDAK 8.32 468.74 677.35 26 1149 TGTGSLSDAK 8.32 468.74 778.39 26 1150 TGVATEYQPEIGWWAGWVER 25.49 779.04 903.45 43 1151 TGVATEYQPEIGWWAGWVER 25.5 779.04 1146.55 43 1152 TGVATEYQPEIGWWAGWVER 25.52 1168.06 1189.57 56 1153 TGVSYPLLADGTR 17.4 675.36 842.47 35 1154 TGVSYPLLADGTR 17.41 675.36 1005.54 35 1155 TGVSYPLLADGTR 17.4 675.36 1092.57 35 1156 TGWAMDIK 16.71 461.23 577.3 25 1157 TGWAMDIK 16.71 461.23 763.38 25 1158 TGWAMDIK 16.72 461.23 820.4 25 1159 TGWATR 9.71 346.18 517.24 20 1160 TGWATR 9.69 346.18 533.28 20 1161 TGWATR 9.69 346.18 590.3 20 1162 TGWC[CAM]FDC[CAM]TPELGWWVGWVK 28.39 795.36 960.51 44 1163 TGWC[CAM]FDC[CAM]TPELGWWVGWVK 28.39 795.36 1017.53 44 1164 TGWC[CAM]FDC[CAM]TPELGWWVGWVK 28.38 795.36 1028.36 44 1165 TGWEGR 9.1 353.17 531.22 21 1166 TGWEGR 9.09 353.17 547.26 21 1167 TGWEGR 9.09 353.17 604.28 21 1168 TGWFVDK 16.08 426.72 694.36 24 1169 TGWFVDK 16.1 426.72 706.32 24 1170 TGWFVDK 16.08 426.72 751.38 24 1171 TGYDTK 2.09 342.66 526.25 20 1172 TGYDTK 2.09 342.66 538.21 20 1173 TGYDTK 2.08 342.66 583.27 20 1174 TGYGVR 8.09 326.67 478.23 19 1175 TGYGVR 8.1 326.67 494.27 19 1176 TGYGVR 8.1 326.67 551.29 19 1177 TGYSAR 2.24 327.66 480.21 19 1178 TGYSAR 2.24 327.66 496.25 19 1179 TGYSAR 2.24 327.66 553.27 19 1180 TGYSTR 2.08 342.67 510.22 20 1181 TGYSTR 2.08 342.67 526.26 20 1182 TGYSTR 2.08 342.67 583.28 20 1183 THESSNWGK 5.36 523.24 678.32 28 1184 THESSNWGK 5.37 523.24 807.36 28 1185 THESSNWGK 5.37 523.24 944.42 28 1186 TIC[CAM]TAIADAGTGK 14.35 639.82 732.39 33 1187 TIC[CAM]TAIADAGTGK 14.35 639.82 904.47 33 1188 TIC[CAM]TAIADAGTGK 14.35 639.82 1064.5 33 1189 TIGGAPDAYWVDDSLQISAR 21.22 712.35 1004.5 40 1190 TIGGAPDAYWVDDSLQISAR 21.22 712.35 1103.57 40 1191 TIGGAPDAYWVDDSLQISAR 21.21 1068.02 1103.57 52 1192 TLPFSASSYETLR 18.73 736.37 855.42 37 1193 TLPFSASSYETLR 18.73 736.37 1013.49 37 1194 TLPFSASSYETLR 18.73 736.37 1160.56 37 1195 TLPFSPK 15 395.23 478.27 22 1196 TLPFSPK 15 395.23 575.32 22 1197 TLPFSPK 15 395.23 688.4 22 1198 TLPFSQEVQDEVQSILFIEEK 28.55 827.09 891.52 45 1199 TLPFSQEVQDEVQSILFIEEK 28.56 827.09 978.55 45 1200 TLPFSQEVQDEVQSILFIEEK 28.56 827.09 1106.61 45 1201 TLPFSQEVQDEVQSMLFIEEK 27.7 833.08 996.51 46 1202 TLPFSQEVQDEVQSMLFIEEK 27.69 833.08 1124.57 46 1203 TLPFSQEVQDEVQSMLFIEEK 27.7 833.08 1223.63 46 1204 TLQNGWFEGFIISK 24.12 820.43 940.51 41 1205 TLQNGWFEGFIISK 24.11 820.43 1126.59 41 1206 TLQNGWFEGFIISK 24.11 820.43 1183.61 41 1207 TMQEYLNK 12.6 513.75 666.35 28 1208 TMQEYLNK 12.6 513.75 794.4 28 1209 TMQEYLNK 12.6 513.75 925.44 28 1210 TQTYQAYDAAR 11.2 644.3 666.32 33 1211 TQTYQAYDAAR 11.2 644.3 957.44 33 1212 TQTYQAYDAAR 11.2 644.3 1058.49 33 1213 TTDPTIWEK 14.39 545.77 676.37 29 1214 TTDPTIWEK 14.39 545.77 773.42 29 1215 TTDPTIWEK 14.39 545.77 888.45 29 1216 TTTTEVFK 12.06 463.75 522.29 25 1217 TTTTEVFK 12.06 463.75 623.34 25 1218 TTTTEVFK 12.06 463.75 724.39 25 1219 TWASNDFSR 13.73 542.25 638.29 29 1220 TWASNDFSR 13.73 542.25 725.32 29 1221 TWASNDFSR 13.73 542.25 796.36 29 1222 TWDMVQR 14.28 468.22 648.31 26 1223 TWDMVQR 14.28 468.22 761.33 26 1224 TWDMVQR 14.28 468.22 834.39 26 1225 TYWDPAR 12.15 460.75 557.3 25 1226 TYWDPAR 12.14 460.75 656.37 25 1227 TYWDPAR 12.15 460.75 819.44 25 1228 VAFSLNIEMK 20.65 576.31 747.41 30 1229 VAFSLNIEMK 20.65 576.31 834.44 30 1230 VAFSLNIEMK 20.65 576.31 981.51 30 1231 VANSLIGLSTGAVR 17.97 679.39 760.43 35 1232 VANSLIGLSTGAVR 17.97 679.39 873.52 35 1233 VANSLIGLSTGAVR 17.97 679.39 986.6 35 1234 VELGK 7.74 273.17 342.2 17 1235 VELGK 7.75 273.17 399.22 17 1236 VELGK 7.74 273.17 446.26 17 1237 VFLDSWAK 18.2 483.26 606.29 26 1238 VFLDSWAK 18.2 483.26 719.37 26 1239 VFLDSWAK 18.2 483.26 866.44 26 1240 VFLESWAK 18.11 490.27 620.3 27 1241 VFLESWAK 18.11 490.27 733.39 27 1242 VFLESWAK 18.11 490.27 880.46 27 1243 VFLSSWAQDMNLSSAIK 23.66 948.98 978.49 47 1244 VFLSSWAQDMNLSSAIK 23.66 948.98 1106.55 47 1245 VFLSSWAQDMNLSSAIK 23.66 948.98 1177.59 47 1246 VGFER 10.32 304.16 433.21 18 1247 VGFER 10.32 304.16 451.23 18 1248 VGFER 10.32 304.16 508.25 18 1249 VILVFDQVR 19.69 544.83 664.34 29 1250 VILVFDQVR 19.69 544.83 763.41 29 1251 VILVFDQVR 19.69 544.83 876.49 29 1252 VMAAMVR 12.3 389.21 476.26 22 1253 VMAAMVR 12.3 389.21 547.3 22 1254 VMAAMVR 12.3 389.21 678.34 22 1255 VPLAVMGYDAGILVDAHNPR 21.61 703.37 709.34 39 1256 VPLAVMGYDAGILVDAHNPR 21.61 703.37 808.41 39 1257 VPLAVMGYDAGILVDAHNPR 21.61 703.37 921.49 39 1258 VQDEVQSMLFIEEK 20.48 847.92 996.51 42 1259 VQDEVQSMLFIEEK 20.48 847.92 1124.57 42 1260 VQDEVQSMLFIEEK 20.47 847.92 1223.63 42 1261 VQDGVQSMLFIEEK 20.26 811.91 996.51 41 1262 VQDGVQSMLFIEEK 20.27 811.91 1124.57 41 1263 VQDGVQSMLFIEEK 20.25 811.91 1223.63 41 1264 VSC[CAM]LPC[CAM]YQVVSHK 14.32 526.26 569.34 30 1265 VSC[CAM]LPC[CAM]YQVVSHK 14.32 526.26 860.46 30 1266 VSC[CAM]LPC[CAM]YQVVSHK 14.31 526.26 1020.49 30 1267 VSC[CAM]VWC[CAM]YQALAR 18.41 756.86 881.43 38 1268 VSC[CAM]VWC[CAM]YQALAR 18.41 756.86 1067.51 38 1269 VSC[CAM]VWC[CAM]YQALAR 18.41 756.86 1166.58 38 1270 VSDVC[CAM]SEVTAEGWQEVR 17.33 650.97 774.39 37 1271 VSDVC[CAM]SEVTAEGWQEVR 17.34 975.95 1075.52 48 1272 VSDVC[CAM]SEVTAEGWQEVR 17.34 975.95 1174.59 48 1273 VSEVEGWQIHGK 13.92 456.9 582.34 27 1274 VSEVEGWQIHGK 13.92 456.9 768.42 27 1275 VSEVEGWQIHGK 13.92 456.9 825.44 27 1276 VSFSLNIEMK 20.65 584.31 834.44 31 1277 VSFSLNIEMK 20.64 584.31 981.51 31 1278 VSFSLNIEMK 20.65 584.31 1068.54 31 1279 VSPC[CAM]SSFK 11.04 456.22 468.25 25 1280 VSPC[CAM]SSFK 11.04 456.22 628.28 25 1281 VSPC[CAM]SSFK 11.04 456.22 725.33 25 1282 VSQVPAYK 10.68 446.25 478.27 25 1283 VSQVPAYK 10.68 446.25 577.33 25 1284 VSQVPAYK 10.68 446.25 705.39 25 1285 WFAR 11.17 296.18 393.22 18 1286 WFAR 11.17 296.18 417.25 18 1287 WFAR 11.17 296.18 492.29 18 1288 WDGAK 4.9 288.64 302.11 18 1289 WDGAK 4.9 288.64 390.2 18 1290 WDGAK 4.9 288.64 430.17 18 1291 WDGHIYDFPDWNR 20.52 574.25 590.27 33 1292 WDGHIYDFPDWNR 20.52 574.25 687.32 33 1293 WDGHIYDFPDWNR 20.52 574.25 887.37 33 1294 WDGIK 12.03 309.67 359.13 19 1295 WDGIK 12.03 309.67 432.25 19 1296 WDGIK 12.03 309.67 472.22 19 1297 WDGKPR 6.36 379.7 457.29 22 1298 WDGKPR 6.35 379.7 572.32 22 1299 WDGKPR 6.36 379.7 584.28 22 1300 WDGQTR 7.41 381.68 461.25 22 1301 WDGQTR 7.41 381.68 576.27 22 1302 WDGQTR 7.41 381.68 588.24 22 1303 WDGVK 10.1 302.66 359.13 18 1304 WDGVK 10.1 302.66 418.23 18 1305 WDGVK 10.1 302.66 458.2 18 1306 WDGVNR 10.39 373.68 445.25 21 1307 WDGVNR 10.39 373.68 560.28 21 1308 WDGVNR 10.42 373.68 572.25 21 1309 YAQAK 12.58 290.66 363.17 18 1310 YAQAK 12.58 290.66 417.25 18 1311 YAQAK 12.58 290.66 434.2 18 1312 YFSDFNAK 14.21 496.23 681.32 27 1313 YFSDFNAK 14.21 496.23 828.39 27 1314 YFSDFNAK 14.21 496.23 828.39 27 1315 YGTHLDR 8.51 431.21 641.34 24 1316 YGTHLDR 8.52 431.21 687.31 24 1317 YGTHLDR 8.51 431.21 698.36 24 1318 YLDELVK 15.52 440.24 488.31 24 1319 YLDELVK 15.53 440.24 603.33 24 1320 YLDELVK 15.52 440.24 716.42 24 1321 YLMITEAGR 15.86 527.27 533.27 28 1322 YLMITEAGR 15.86 527.27 646.35 28 1323 YLMITEAGR 15.86 527.27 777.39 28 1324 YLNLFSYGNANIGGGIDK 22.16 639.32 773.42 36 1325 YLNLFSYGNANIGGGIDK 22.16 958.48 1015.52 47 1326 YLNLFSYGNANIGGGIDK 22.16 958.48 1178.58 47 1327 YPVVWYSQQVAHHLGAQR 18.11 535.53 544.32 30 1328 YPVVWYSQQVAHHLGAQR 18.11 535.53 681.38 30 1329 YPVVWYSQQVAHHLGAQR 18.11 535.53 889.48 30 1330 YSNVLAFK 16.44 471.26 478.3 26 1331 YSNVLAFK 16.44 471.26 691.41 26 1332 YSNVLAFK 16.44 471.26 778.45 26 1333 YSPASTFK 12.22 450.73 553.3 25 1334 YSPASTFK 12.22 450.73 650.35 25 1335 YSPASTFK 12.22 450.73 737.38 25 1336 YSVVPVYQQLAR 18.42 711.89 778.42 36 1337 YSVVPVYQQLAR 18.42 711.89 974.54 36 1338 YSVVPVYQQLAR 18.43 711.89 1073.61 36 1339 YSVVWYSQLTAK 19.75 722.88 810.44 37 1340 YSVVWYSQLTAK 19.76 722.88 996.51 37 1341 YSVVWYSQLTAK 19.76 722.88 1095.58 37 1342 YSVVWYSQQVAHHLGAQR 18.61 533.02 544.32 30 1343 YSVVWYSQQVAHHLGAQR 18.61 533.02 681.38 30 1344 YSVVWYSQQVAHHLGAQR 18.61 533.02 889.48 30 1345 YTPASTFK 11.95 305.49 553.3 19 1346 YTPASTFK 11.98 457.73 553.3 25 1347 YTPASTFK 11.98 457.73 650.35 25 1348 YTSAFGYGNADVSGEPGK 15.03 607.28 673.35 34 1349 YTSAFGYGNADVSGEPGK 15.02 607.28 788.38 34 1350 YTSAFGYGNADVSGEPGK 15.02 910.41 1030.48 45 1351 YVFVSALTGNLGSNLTSSIK 23.66 691.04 906.49 39 1352 YVFVSALTGNLGSNLTSSIK 23.66 1036.06 1165.63 51 1353 YVFVSALTGNLGSNLTSSIK 23.67 1036.06 1190.64 51 1354 YVFVSALTGSLGSNLTSSIK 24.04 682.04 906.49 38 1355 YVFVSALTGSLGSNLTSSIK 24.04 1022.55 1106.61 50 1356 YVFVSALTGSLGSNLTSSIK 24.04 1022.55 1163.63 50

The areas obtained for each of the transitions and for each of the microorganisms studied were measured. When the areas of the three transitions of the same peptide are greater than or equal to 2500, the detection of the peptide is considered to be positive and is labelled “1”. When at least one transition comprises an area less than 2500, the corresponding peptide is considered non-detected and is labelled “0”.

EXAMPLE 17 Identification of a Resistance to IMP Beta-Lactams

Samples Sam145 to Sam154 are identified according to one of the methods described in examples 1, 3 or 4. The identification of the species is set out in TABLE 26.

TABLE 26 Names Species Sam145 A. baumannii Sam146 A. baumannii Sam147 E. coli Sam148 K. pneumoniae Sam149 K. pneumoniae Sam150 P. aeruginosa Sam151 P. aeruginosa Sam152 P. aeruginosa Sam153 P. aeruginosa Sam154 P. putida

Samples Sam145 to Sam154 correspond to a species able to comprise an IMP resistance mechanism. The following method is then performed to detect such a mechanism.

Each sample is treated according to Example 5, then analysed according to Example 6 unless otherwise stated in the rest of the example, by detecting the peptides from TABLE 27 instead of the peptides from TABLE 3.

TABLE 27 Retention (m/z) (m/z) Collision Transition time filtered in filtered in energy Positivity number Peptide (minutes) Q1 Q3 (eV) threshold 1 DTENLVNWFVER 24.3 761.37 550.3 39.1 2000 2 DTENLVNWFVER 24.3 761.37 850.42 39.1 2000 3 DTENLVNWFVER 24.3 761.37 949.49 39.1 2000 4 GDASLMK 10.6 361.18 391.24 16.3 2000 5 GDASLMK 10.6 361.18 478.27 16.3 2000 6 GDASLMK 10.6 361.18 549.31 16.3 2000 7 GFNESK 2 341.16 312.65 15.2 2000 8 GFNESK 2 341.16 363.19 15.2 2000 9 GFNESK 2 341.16 477.23 15.2 2000 10 GLNESK 1.1 324.17 363.19 14.2 2000 11 GLNESK 1.1 324.17 477.23 14.2 2000 12 GLNESK 1.1 324.17 590.31 14.2 2000 13 GLNESR 2.2 338.18 309.66 15 2000 14 GLNESR 2.2 338.18 391.19 15 2000 15 GLNESR 2.1 338.18 505.24 15 2000 16 GVYVHTSFEEVK 15.1 465.57 488.74 21.5 2000 17 GVYVHTSFEEVK 15.1 465.57 538.28 21.5 2000 18 GVYVHTSFEEVK 15.1 465.57 619.81 21.5 2000 19 GWGVVTK 14.3 373.71 345.2 17 2000 20 GWGVVTK 14.3 373.71 347.23 17 2000 21 GWGVVTK 14.3 373.71 503.32 17 2000 22 GWSVVTK 14.2 388.72 347.23 17.9 2000 23 GWSVVTK 14.2 388.72 446.3 17.9 2000 24 GWSVVTK 14.2 388.72 533.33 17.9 2000 25 HGLVVLVK 15.4 432.79 557.4 20.4 2000 26 HGLVVLVK 15.5 432.79 670.49 20.4 2000 27 HGLVVLVK 15.4 432.79 727.51 20.4 2000 28 HSFNGVSYSLIK 17 451.24 460.31 21.1 2000 29 HSFNGVSYSLIK 17 451.24 623.38 21.1 2000 30 HSFNGVSYSLIK 17 451.24 710.41 21.1 2000 31 LEEGVYVHTSFEEVK 16.9 589.29 697.85 25.4 2000 32 LEEGVYVHTSFEEVK 16.9 589.29 762.37 25.4 2000 33 LEEGVYVHTSFEEVK 16.9 589.29 826.89 25.4 2000 34 LFVLCVCFLCSITAAGAR 19.5 686.68 659.38 28.4 2000 35 LFVLCVCFLCSITAAGAR 19.6 686.68 906.45 28.4 2000 36 LFVLCVCFLCSITAAGAR 19.5 1029.52 374.22 54.4 2000 37 LFVLCVCFLCSITAAGAR 19.5 1029.52 659.38 54.4 2000 38 LTLEQAVK 15.2 451.27 574.32 21.5 2000 39 LTLEQAVK 15.2 451.27 687.4 21.5 2000 40 LTLEQAVK 15.2 451.27 788.45 21.5 2000 41 LTWEQAVK 16.3 487.77 574.32 23.5 2000 42 LTWEQAVK 16.3 487.77 760.4 23.5 2000 43 LTWEQAVK 16.3 487.77 861.45 23.5 2000 44 LTWEQTVK 15.4 502.77 395.71 24.4 2000 45 LTWEQTVK 15.4 502.77 604.33 24.4 2000 46 LTWEQTVK 15.4 502.77 790.41 24.4 2000 47 LVAWFVGR 21.3 474.28 478.28 22.8 2000 48 LVAWFVGR 21.3 474.28 664.36 22.8 2000 49 LVAWFVGR 21.3 474.28 735.39 22.8 2000 50 LVNWFIEHGYR 20.1 478.58 611.29 21.9 2000 51 LVNWFIEHGYR 20.1 478.58 660.83 21.9 2000 52 LVNWFIEHGYR 20.1 478.58 661.31 21.9 2000 53 LVNWFVER 20.9 531.79 550.3 26 2000 54 LVNWFVER 20.9 531.79 736.38 26 2000 55 LVNWFVER 20.9 531.79 850.42 26 2000 56 LVTWFVER 20.6 525.29 550.3 25.7 2000 57 LVTWFVER 20.6 525.29 736.38 25.7 2000 58 LVTWFVER 20.6 525.29 837.43 25.7 2000 59 LVVPGHSEVGDASLLK 17.6 540.97 655.34 23.9 2000 60 LVVPGHSEVGDASLLK 17.6 540.97 704.88 23.9 2000 61 LVVPGHSEVGDASLLK 17.6 810.95 655.34 42 2000 62 LVVPSHSDIGDASLLK 18 550.97 670.35 24.2 2000 63 LVVPSHSDIGDASLLK 18 550.97 719.88 24.2 2000 64 LVVPSHSDIGDASLLK 18 825.96 670.35 42.8 2000 65 LVVPSHSDIGDSSLLK 17.7 556.31 678.34 24.3 2000 66 LVVPSHSDIGDSSLLK 17.7 556.31 719.39 24.3 2000 67 LVVPSHSDIGDSSLLK 17.7 556.31 727.88 24.3 2000 68 LVVPSHSDVGDASLLK 17.5 546.3 663.34 24 2000 69 LVVPSHSDVGDASLLK 17.5 546.3 712.87 24 2000 70 LVVPSHSDVGDASLLK 17.5 818.95 663.34 42.4 2000 71 LVVPSHSEAGDASLLK 16.1 541.63 656.33 23.9 2000 72 LVVPSHSEAGDASLLK 16.1 541.63 705.87 23.9 2000 73 LVVPSHSEAGDASLLK 16.1 541.63 755.4 23.9 2000 74 LVVPSHSEVGDASLLK 17.5 550.97 670.35 24.2 2000 75 LVVPSHSEVGDASLLK 17.5 550.97 719.88 24.2 2000 76 LVVPSHSEVGDASLLK 17.5 825.96 670.35 42.8 2000 77 LVVSGHSEIGNASLLK 16.8 541.97 656.85 23.9 2000 78 LVVSGHSEIGNASLLK 16.8 541.97 706.38 23.9 2000 79 LVVSGHSEIGNASLLK 16.8 541.97 755.92 23.9 2000 80 LVVSSHSDIGDVSLLK 18.9 556.98 679.35 24.3 2000 81 LVVSSHSDIGDVSLLK 18.9 556.98 728.89 24.3 2000 82 LVVSSHSDIGDVSLLK 18.9 556.98 778.42 24.3 2000 83 LVVSSHSEIGDASLLK 17.6 552.31 672.34 24.2 2000 84 LWSSHSEIGDASLLK 17.6 552.31 721.88 24.2 2000 85 LWSSHSEIGDASLLK 17.6 552.31 771.41 24.2 2000 86 LVVSSHSEIGNASLLQR 16.8 604 416.26 25.8 2000 87 LVVSSHSEIGNASLLQR 16.8 604 616.38 25.8 2000 88 LWSSHSEIGNASLLQR 16.8 604 799.42 25.8 2000 89 LVVSSHSEK 8.1 329.18 387.19 17.3 2000 90 LVVSSHSEK 8.1 329.18 587.28 17.3 2000 91 LVVSSHSEK 8.1 493.27 773.38 23.9 2000 92 LVVSSHSETGNASLLK 14.7 547.97 665.83 24.1 2000 93 LVVSSHSETGNASLLK 14.7 547.97 715.37 24.1 2000 94 LVVSSHSETGNASLLK 14.7 547.97 764.9 24.1 2000 95 NDAYLIDTPITAK 18.8 717.88 745.41 36.7 2000 96 NDAYLIDTPITAK 18.8 717.88 858.49 36.7 2000 97 NDAYLIDTPITAK 18.8 717.88 971.58 36.7 2000 98 NSFGGVNYWLVK 21.4 692.36 822.45 35.2 2000 99 NSFGGVNYWLVK 21.4 692.36 1035.56 35.2 2000 100 NSFGGVNYWLVK 21.4 692.36 1182.63 35.2 2000 101 NSFSGASYWLVK 20.8 679.84 795.44 34.5 2000 102 NSFSGASYWLVK 20.8 679.84 923.5 34.5 2000 103 NSFSGASYWLVK 20.8 679.84 1010.53 34.5 2000 104 NSFSGGSYWLVNNK 18.8 786.88 375.2 40.6 2000 105 NSFSGGSYWLVNNK 18.8 786.88 474.27 40.6 2000 106 NSFSGGSYWLVNNK 18.8 786.88 1224.6 40.6 2000 107 NSFSGVSYWLLK 23.6 700.86 809.46 35.7 2000 108 NSFSGVSYWLLK 23.6 700.86 1052.58 35.7 2000 109 NSFSGVSYWLLK 23.6 700.86 1199.65 35.7 2000 110 NSFSGVSYWLVK 22.3 693.86 795.44 35.3 2000 111 NSFSGVSYWLVK 22.3 693.86 951.53 35.3 2000 112 NSFSGVSYWLVK 22.3 693.86 1038.56 35.3 2000 113 SIPTYASELTNELLK 23.8 560.3 717.41 24.5 2000 114 SIPTYASELTNELLK 23.8 560.3 739.89 24.5 2000 115 SIPTYASELTNELLK 23.8 839.95 739.89 43.6 2000 116 TLEQAVK 10.5 394.73 445.28 18.2 2000 117 TLEQAVK 10.5 394.73 574.32 18.2 2000 118 TLEQAVK 10.5 394.73 687.4 18.2 2000 119 TWEQALK 15.1 438.24 459.29 20.7 2000 120 TWEQALK 15.1 438.24 588.34 20.7 2000 121 TWEQALK 15.1 438.24 774.41 20.7 2000 122 TWEQAVK 12.8 431.23 445.28 20.3 2000 123 TWEQAVK 12.8 431.23 574.32 20.3 2000 124 TWEQAVK 12.8 431.23 760.4 20.3 2000 125 VQATNSFSGVNYWLVK 22.1 604.98 708.41 25.8 2000 126 VQATNSFSGVNYWLVK 22.1 604.98 822.45 25.8 2000 127 VQATNSFSGVNYWLVK 22.1 906.97 1212.64 47.4 2000 128 VQATNSFSGVSYSLIK 19.9 567.63 710.41 24.7 2000 129 VQATNSFSGVSYSLIK 19.9 567.63 953.53 24.7 2000 130 VQATNSFSGVSYSLIK 19.9 850.95 710.41 44.2 2000 131 VQATNSFSGVSYWLVK 22.5 595.98 708.41 25.6 2000 132 VQATNSFSGVSYWLVK 22.5 595.98 795.44 25.6 2000 133 VQATNSFSGVSYWLVK 22.5 893.46 1038.56 46.7 2000 134 YSFSEVSYWLVK 23.8 754.38 795.44 38.7 2000 135 YSFSEVSYWLVK 23.8 754.38 894.51 38.7 2000 136 YSFSEVSYWLVK 23.8 754.38 1110.58 38.7 2000 137 YSFSGVSYWLVK 23.4 718.37 795.44 36.7 2000 138 YSFSGVSYWLVK 23.4 718.37 951.53 36.7 2000 139 YSFSGVSYWLVK 23.4 718.37 1185.63 36.7 2000

-   -   The other machine parameters used are as follows:     -   Scan type: MRM     -   MRM planned: yes     -   Polarity: Positive     -   Ionising source: Turbo V™ (Applied BioSystems)     -   Q1 setting: Filtering with unit resolution     -   Q3 setting: Filtering with unit resolution     -   Inter-scan pause: 5.00 msec     -   Scanning speed: 10 Da/s     -   Curtain gas: 50.00 psi     -   Cone voltage: 5500.00 V     -   Source temperature: 500.00° C.     -   Nebulising gas: 50.00 psi     -   Heating gas: 50.00 psi     -   Collision gas which induces dissociation: 9.00 psi     -   Dynamic filling: activated     -   Declustering potential (DP): 100.00 V     -   Entry potential before Q0 (EP): 6.00 V     -   Collision cell exit potential (CXP): 15 V     -   Total cycle time: 1 sec     -   Detection window: 120 sec

The areas obtained for each of the transitions and for each of the microorganisms studied were measured. When the areas of the transitions are greater than or equal to the positivity threshold described in TABLE 27, the detection of the transition is considered to be positive and is labelled “1” in TABLE 28. When a transition has an area less than the positivity threshold described in TABLE 27, the transition is considered non-detected and is labelled “0” in TABLE 28.

For a given peptide, when at least 3 transitions are labelled “1”, the peptide is considered as being detected.

TABLE 28 Transition number Sam145 Sam146 Sam147 Sam148 Sam149 Sam150 Sam151 Sam152 Sam153 Sam154 1 0 0 1 0 0 0 0 0 0 0 2 0 0 1 0 0 0 0 0 0 0 3 0 0 0 0 0 0 0 0 0 0 4 0 0 0 0 0 0 0 0 1 0 5 0 0 0 0 0 0 0 0 1 0 6 0 0 0 0 0 0 0 0 1 0 7 0 0 0 0 0 0 0 0 0 0 8 0 0 0 0 0 0 0 0 0 0 9 0 0 0 0 0 0 0 0 0 0 10 1 1 0 0 0 0 0 0 0 0 11 1 1 0 0 0 0 0 0 0 0 12 0 0 0 0 0 0 0 0 0 0 13 0 0 0 0 0 0 0 0 0 0 14 0 0 0 0 0 0 0 0 0 0 15 0 0 0 0 0 0 0 0 0 0 16 0 0 0 0 0 0 0 0 0 0 17 0 0 0 0 0 1 1 0 1 0 18 0 0 0 0 0 0 0 0 0 0 19 0 1 0 0 0 0 0 0 0 0 20 0 0 0 0 0 1 0 1 1 0 21 0 0 0 0 0 0 0 1 0 0 22 0 0 0 0 1 0 0 0 0 0 23 0 0 1 1 1 0 0 0 1 0 24 0 0 0 0 0 0 0 0 0 0 25 0 0 0 0 0 0 0 0 0 0 26 0 0 0 0 0 0 0 0 0 0 27 0 0 0 0 0 0 0 0 0 0 28 0 0 0 0 0 0 0 0 0 0 29 0 0 0 0 0 0 0 0 0 0 30 0 0 0 0 0 0 0 0 0 0 31 0 0 0 0 0 0 0 0 0 0 32 0 0 0 0 0 0 0 0 0 0 33 1 0 0 0 0 0 0 0 0 0 34 0 0 0 0 0 0 0 0 0 0 35 0 0 0 0 0 0 0 0 0 0 36 0 0 0 0 0 0 0 0 0 0 37 0 0 0 0 0 0 0 0 0 0 38 0 1 1 1 0 0 0 1 0 0 39 0 1 1 1 0 0 0 1 0 0 40 0 1 1 1 0 0 0 1 0 0 41 0 0 1 0 0 0 0 0 0 1 42 0 0 0 0 0 0 0 0 0 1 43 0 0 0 0 0 0 0 0 0 1 44 0 0 0 0 0 0 0 0 0 0 45 0 0 0 0 0 0 0 0 0 0 46 0 0 0 0 0 0 0 0 0 0 47 0 0 0 0 0 0 0 0 0 0 48 0 0 0 0 0 0 0 0 0 1 49 0 0 0 0 0 0 0 0 0 0 50 0 0 0 0 0 0 0 0 0 0 51 0 0 0 0 0 0 0 0 0 0 52 0 0 0 0 0 1 0 0 0 0 53 1 0 0 0 1 1 0 0 1 0 54 1 0 1 0 0 1 0 0 1 0 55 1 1 1 0 1 1 0 0 1 0 56 0 1 1 1 1 0 1 1 0 0 57 0 1 1 1 1 0 1 1 0 0 58 0 1 1 1 1 0 1 1 0 0 59 0 0 0 0 0 1 1 0 0 0 60 0 0 0 0 0 1 1 0 0 0 61 0 0 0 0 0 1 1 0 0 0 62 0 0 0 1 0 0 1 1 0 0 63 0 0 0 1 0 0 1 1 0 0 64 0 0 0 1 0 0 1 1 0 0 65 0 0 0 0 0 1 1 1 1 0 66 0 0 0 0 0 0 0 0 0 0 67 0 0 0 0 0 0 0 0 0 0 68 0 0 0 0 0 0 0 0 0 0 69 0 0 0 0 0 0 0 0 0 0 70 0 1 0 0 0 0 0 0 0 0 71 1 1 1 0 0 0 0 0 0 0 72 0 1 1 0 0 0 0 0 0 0 73 0 1 1 0 0 0 0 0 0 0 74 0 0 0 1 0 0 1 1 0 0 75 0 0 0 1 0 0 1 1 0 0 76 0 0 0 1 0 0 1 1 0 0 77 0 0 0 0 0 0 0 0 0 1 78 0 0 0 0 0 0 0 0 0 1 79 0 1 1 0 0 0 0 0 0 1 80 0 0 0 0 0 0 0 0 0 0 81 0 0 0 0 0 0 0 0 0 0 82 0 1 0 0 0 0 0 0 0 0 83 1 0 0 0 1 1 0 0 0 1 84 1 0 0 0 1 1 0 0 1 0 85 1 0 1 1 1 1 1 1 1 0 86 0 0 1 0 0 0 0 0 0 0 87 0 0 1 0 0 0 0 0 0 0 88 0 0 0 0 0 0 0 0 0 0 89 0 0 0 0 0 0 0 0 0 0 90 0 0 0 0 0 0 0 0 1 0 91 0 0 0 0 0 0 0 0 1 0 92 1 0 0 0 0 0 0 0 0 0 93 0 0 0 0 0 0 0 0 0 0 94 0 0 0 0 0 0 0 0 0 0 95 0 1 0 0 0 0 0 0 0 0 96 0 0 0 0 0 0 0 0 0 0 97 0 0 0 0 0 0 0 0 0 0 98 0 1 1 0 0 0 0 0 0 0 99 0 1 1 0 0 0 0 0 0 0 100 0 1 1 1 0 0 0 0 0 0 101 0 0 0 0 0 0 0 0 0 0 102 0 0 0 0 0 0 0 0 0 0 103 0 0 0 0 0 0 1 1 0 0 104 0 0 0 1 0 0 0 0 0 0 105 0 0 0 1 1 0 0 0 0 0 106 0 0 0 0 0 0 0 0 0 0 107 0 0 0 0 0 0 0 0 0 0 108 0 0 0 0 0 0 0 0 0 0 109 0 0 0 0 0 0 0 0 0 0 110 1 1 0 0 0 0 0 0 0 0 111 1 1 0 0 0 0 0 0 1 0 112 1 0 0 0 0 0 0 0 0 0 113 0 0 0 1 0 0 0 0 0 0 114 0 0 0 1 0 0 0 1 0 0 115 0 0 0 1 0 0 0 0 0 0 116 0 1 0 1 0 0 1 0 0 0 117 0 1 1 1 0 0 1 0 0 0 118 0 1 0 1 0 0 1 0 0 0 119 0 0 0 0 0 0 0 0 1 0 120 0 0 0 0 0 0 0 0 1 0 121 0 0 0 0 0 0 0 0 1 0 122 1 0 0 0 1 1 0 0 0 0 123 1 0 0 0 1 1 0 0 0 0 124 1 0 0 0 1 1 0 0 0 0 125 0 0 0 0 0 0 0 0 0 0 126 0 0 0 0 0 0 0 1 0 0 127 0 0 0 1 1 0 0 0 0 0 128 0 0 0 0 0 0 0 0 0 1 129 0 0 0 0 0 0 0 0 0 0 130 0 0 0 0 0 0 0 0 0 0 131 0 0 0 0 0 0 0 0 0 0 132 0 0 0 0 0 0 0 0 0 0 133 0 0 0 0 0 0 0 0 0 0 134 0 0 0 0 0 0 0 0 0 0 135 0 0 0 0 0 0 1 0 0 0 136 0 0 0 0 0 0 0 0 0 0 137 1 0 0 0 0 0 0 0 0 0 138 0 0 0 0 0 0 0 0 0 0 139 0 0 0 0 0 0 0 0 0 0

Samples Sam145 to Sam154 comprise at least one peptide which is characteristic of IMPs. The bacteria present in samples Sam145 to Sam154 therefore express a beta-lactamase which confers on them a resistance to penicillins, to cephalosporins and to carbapenems.

EXAMPLE 18 Identification of a Resistance to OXA-48 Beta-Lactams

Samples Sam155 to Sam164 are identified according to one of the methods described in examples 1, 3 or 4. The identification of the species is set out in TABLE 29.

TABLE 29 Names Species Sam155 K. pneumoniae Sam156 K. pneumoniae Sam157 K. pneumoniae Sam158 E. cloacae Sam159 E. cloacae Sam160 K. pneumoniae Sam161 K. pneumoniae Sam162 K. pneumoniae Sam163 K. pneumoniae Sam164 K. pneumoniae

Samples Sam155 to Sam164 correspond to a species able to comprise an OXA-48 resistance mechanism. The following method is then performed to detect such a mechanism.

Each sample is treated according to Example 5, then analysed according to Example 6 unless otherwise stated in the rest of the example, by detecting the peptides from TABLE 30 instead of the peptides from TABLE 3.

TABLE 30 Charge Tran- state of Retention (m/z) (m/z) Collision sition the time filtered filtered energy Positivity number Peptide precursor Fragment ion (minutes) in Q1 in Q3 (eV) threshold 1 ANQAFLPASTFK 2 y6 monocharged 18.09 647.84 650.35 32.7 2000 2 ANQAFLPASTFK 2 y7 monocharged 18.11 647.84 763.44 32.7 2000 3 ANQAFLPASTFK 2 y8 monocharged 18.09 647.84 910.5 32.7 2000 4 DEHQVFK 3 y5 dicharged 9.89 301.48 329.69 16.4 2000 5 DEHQVFK 2 y4 monocharged 9.89 451.72 521.31 21.5 2000 6 DEHQVFK 2 y5 monocharged 9.91 451.72 658.37 21.5 2000 7 DHNLITAMK 3 y3 monocharged 14.57 348.18 349.19 17.9 2000 8 DHNLITAMK 3 y4 monocharged 14.57 348.18 450.24 17.9 2000 9 DHNLITAMK 2 y7 monocharged 14.57 521.77 790.45 25.5 2000 10 DIATWNR 2 y3 monocharged 13.79 438.22 475.24 20.7 2000 11 DIATWNR 2 y4 monocharged 13.79 438.22 576.29 20.7 2000 12 DIATWNR 2 y5 monocharged 13.79 438.22 647.33 20.7 2000 13 IPNSLIALDLGVVK 3 y6 monocharged 23.68 484.63 630.38 22.1 2000 14 IPNSLIALDLGVVK 2 y13 dicharged 23.68 726.45 669.9 37.1 2000 15 IPNSLIALDLGVVK 2 y8 monocharged 23.68 726.45 814.5 37.1 2000 16 ISATEQISFLR 2 y4 monocharged 19.17 632.85 522.3 31.8 2000 17 ISATEQISFLR 2 y5 monocharged 19.17 632.85 635.39 31.8 2000 18 ISATEQISFLR 2 y6 monocharged 19.17 632.85 763.45 31.8 2000 19 QAMLTEANGDYIIR 3 y4 monocharged 18.36 532.27 564.35 23.6 2000 20 QAMLTEANGDYIIR 3 y6 monocharged 18.36 532.27 736.4 23.6 2000 21 QAMLTEANGDYIIR 2 y10 monocharged 18.36 797.9 1151.57 41.2 2000 22 QQGFTNNLK 2 y4 monocharged 12.58 525.27 488.28 25.7 2000 23 QQGFTNNLK 2 y5 monocharged 12.58 525.27 589.33 25.7 2000 24 QQGFTNNLK 2 y7 monocharged 12.58 525.27 793.42 25.7 2000 25 SQGVVVLWNENK 2 y5 monocharged 18.54 686.87 690.32 34.9 2000 26 SQGVVVLWNENK 2 y6 monocharged 18.54 686.87 803.41 34.9 2000 27 SQGVVVLWNENK 2 y7 monocharged 18.52 686.87 902.47 34.9 2000 28 SWNAHFTEHK 3 y8 dicharged 12.23 419.53 492.24 20.1 2000 29 SWNAHFTEHK 3 y9 dicharged 12.23 419.53 585.28 20.1 2000 30 SWNAHFTEHK 3 y5 monocharged 12.23 419.53 661.33 20.1 2000 31 VLALSAVFLVASIIGMPAVAK 3 y6 monocharged 34.92 690.75 616.35 28.5 2000 32 VLALSAVFLVASIIGMPAVAK 3 y7 monocharged 34.94 690.75 673.37 28.5 2000 33 VLALSAVFLVASIIGMPAVAK 3 y8 monocharged 34.94 690.75 786.45 28.5 2000 34 YSVVPVYQEFAR 3 y5 monocharged 20.05 486.59 650.33 22.2 2000 35 YSVVPVYQEFAR 2 y8 dicharged 20.07 729.38 505.26 37.3 2000 36 YSVVPVYQEFAR 2 y8 monocharged 20.07 729.38 1009.51 37.3 2000

-   -   The other machine parameters used are as follows:     -   Scan type: MRM     -   MRM planned: no     -   Polarity: Positive     -   Ionising source: Turbo V™ (Applied BioSystems)     -   Q1 setting: Filtering with unit resolution     -   Q3 setting: Filtering with unit resolution     -   Inter-scan pause: 5.00 msec     -   Scanning speed: 10 Da/s     -   Curtain gas: 40.00 psi     -   Cone voltage: 5500.00 V     -   Source temperature: 500.00° C.     -   Nebulising gas: 50.00 psi     -   Heating gas: 50.00 psi     -   Collision gas which induces dissociation: 9.00 psi     -   Dynamic filling: activated     -   Declustering potential (DP): 100.00 V     -   Entry potential before Q0 (EP): 6.00 V     -   Collision cell exit potential (CXP): 15 V     -   Total cycle time: 1.1 sec

The areas obtained for each of the transitions and for each of the microorganisms studied were measured. When the areas of the transitions are greater than or equal to the positivity threshold described in TABLE 30, the detection of the transition is considered to be positive and is labelled “1” in TABLE 31. When a transition has an area less than the positivity threshold described in TABLE 30, the transition is considered non-detected and is labelled “0” in TABLE 31.

For a given peptide, when at least 3 transitions are labelled “1”, the peptide is considered as being detected.

TABLE 31 Transition number Sam155 Sam156 Sam157 Sam158 Sam159 Sam160 Sam161 Sam162 Sam163 Sam164 1 0 1 1 0 1 1 1 1 1 0 2 0 1 1 0 1 1 1 0 1 0 3 0 1 0 0 0 1 1 0 0 0 4 0 0 0 0 0 0 0 0 0 0 5 0 0 0 0 0 0 0 0 0 0 6 0 0 0 0 0 0 0 0 0 0 7 0 1 0 0 0 1 1 0 0 0 8 0 1 1 1 0 1 1 0 1 0 9 1 1 1 1 1 1 1 1 1 0 10 0 0 0 0 0 0 0 0 0 0 11 0 0 0 1 1 0 0 0 0 0 12 0 0 0 0 0 0 0 1 0 0 13 0 1 1 1 1 1 1 1 1 0 14 0 1 1 1 1 1 1 1 1 1 15 0 1 1 1 1 1 1 1 1 0 16 1 1 1 1 1 1 1 1 1 1 17 1 1 1 1 1 1 1 1 1 1 18 1 1 1 1 1 1 1 1 1 1 19 1 1 1 1 1 1 1 1 1 1 20 1 1 1 1 1 1 1 1 1 0 21 1 1 1 1 1 1 1 1 1 1 22 1 1 1 1 1 1 1 1 1 0 23 1 1 1 1 1 1 1 1 1 1 24 1 1 1 1 1 1 1 1 1 0 25 0 0 0 0 0 0 0 0 0 0 26 0 0 0 0 0 0 0 0 0 0 27 0 0 0 0 0 0 0 0 0 0 28 1 1 1 1 1 1 1 1 1 1 29 1 1 1 1 1 1 1 1 1 1 30 1 1 1 1 1 1 1 1 1 0 31 1 0 0 0 1 0 0 0 0 0 32 1 1 1 1 1 1 1 1 1 0 33 1 1 0 1 1 1 1 1 1 0 34 0 1 1 0 1 1 1 0 1 0 35 0 1 1 0 1 1 1 0 1 0 36 0 1 1 0 1 1 1 0 1 0

Samples Sam155 to Sam164 comprise at least one peptide which is characteristic of the OXA-48 group. The bacteria present in samples Sam155 to Sam164 therefore express a beta-lactamase which confers on them a resistance to penicillins, to first-generation and second-generation cephalosporins (but not to broad-spectrum cephalosporins), and to carbapenems.

EXAMPLE 19 Identification of a Resistance to VIM Beta-Lactams

Samples Sam165 to Sam170 are identified according to one of the methods described in examples 1, 3 or 4. The identification of the species is set out in TABLE 32.

TABLE 32 Names Species Sam165 P. aeruginosa Sam166 E. coli Sam167 A. baumannii complex Sam168 A. junii Sam169 E. coli Sam170 K. pneumoniae ssp pneumoniae

Samples Sam165 to Sam170 correspond to a species able to comprise a VIM resistance mechanism. The following method is then performed to detect such a mechanism.

Each sample is treated according to Example 5, then analysed according to Example 6 unless otherwise stated in the rest of the example, by detecting the peptides from TABLE 33 instead of the peptides from TABLE 3.

TABLE 33 Retention (m/z) (m/z) Collision Transition time filtered in filtered in energy Positivity number Peptide (minutes) Q1 Q3 (eV) threshold 1 AAGVATYASPSAR 12.3 611.32 588.31 30.6 2500 2 AAGVATYASPSAR 12.3 611.32 852.42 30.6 2500 3 AAGVATYASPSAR 12.3 611.32 923.46 30.6 2500 4 AAGVATYASPSIR 14.5 632.34 630.36 31.8 2500 5 AAGVATYASPSIR 14.5 632.34 894.47 31.8 2500 6 AAGVATYASPSIR 14.5 632.34 965.51 31.8 2500 7 AAGVATYASPSTR 12 626.32 618.32 31.4 2500 8 AAGVATYASPSTR 12 626.32 882.43 31.4 2500 9 AAGVATYASPSTR 12 626.32 953.47 31.4 2500 10 AAGVATYTSPLTR 15.7 654.35 674.38 33 2500 11 AAGVATYTSPLTR 15.7 654.35 938.49 33 2500 12 AAGVATYTSPLTR 15.7 654.35 1009.53 33 2500 13 AGVATYASPSTR 11.8 590.8 547.28 29.4 2500 14 AGVATYASPSTR 11.8 590.8 618.32 29.4 2500 15 AGVATYASPSTR 11.8 590.8 781.38 29.4 2500 16 ALSSSGDVVR 11.3 495.76 632.34 24 2500 17 ALSSSGDVVR 11.3 495.76 719.37 24 2500 18 ALSSSGDVVR 11.3 495.76 806.4 24 2500 19 AVSTHFHDDR 9.2 395.52 413.68 19.3 2500 20 AVSTHFHDDR 9.2 395.52 507.72 19.3 2500 21 AVSTHFHDDR 9.2 395.52 689.3 19.3 2500 22 DADELLLIDTAWGAK 24.3 544.28 748.36 24 2500 23 DADELLLIDTAWGAK 24.3 815.92 544.31 42.2 2500 24 DADELLLIDTAWGAK 24.3 815.92 748.36 42.2 2500 25 DADELLLIDTAWGAK 24.3 815.92 861.45 42.2 2500 26 DGDELLLIDTAWGAK 24 539.61 748.36 23.8 2500 27 DGDELLLIDTAWGAK 24 808.91 748.36 41.8 2500 28 DGDELLLIDTAWGAK 24 808.91 861.45 41.8 2500 29 DGDELLLIDTAWGTK 24.1 549.61 778.37 24.1 2500 30 DGDELLLIDTAWGTK 24.1 823.92 778.37 42.7 2500 31 DGDELLLIDTAWGTK 24.1 823.92 891.46 42.7 2500 32 ESAGNVADANLAEWPATIK 20.2 652.99 529.33 27.3 2500 33 ESAGNVADANLAEWPATIK 20.2 652.99 715.41 27.3 2500 34 ESAGNVADANLAEWPATIK 20.2 978.99 529.33 51.5 2500 35 GEYPTVSEIPVGEVR 18.4 544.61 656.37 24 2500 36 GEYPTVSEIPVGEVR 18.4 816.42 641.85 42.3 2500 37 GEYPTVSEIPVGEVR 18.4 816.42 656.37 42.3 2500 38 HTTNVVK 1.3 399.73 345.25 18.5 2500 39 HTTNVVK 1.3 399.73 560.34 18.5 2500 40 HTTNVVK 1.3 399.73 661.39 18.5 2500 41 IGDGVWSHIATQK 17 471.25 563.8 21.7 2500 42 IGDGVWSHIATQK 17 471.25 621.32 21.7 2500 43 IGDGVWSHIATQK 17 471.25 649.83 21.7 2500 44 LGDTVYSSNGLIVR 17.9 747.4 387.27 38.3 2500 45 LGDTVYSSNGLIVR 17.9 747.4 845.48 38.3 2500 46 LGDTVYSSNGLIVR 17.9 747.4 1008.55 38.3 2500 47 LYQIADGVWSHIATK 20.8 567.97 592.81 24.7 2500 48 LYQIADGVWSHIATK 20.8 567.97 649.35 24.7 2500 49 LYQIADGVWSHIATK 20.8 567.97 713.38 24.7 2500 50 LYQIADGVWSHIATR 21 577.31 606.81 25 2500 51 LYQIADGVWSHIATR 21 577.31 663.35 25 2500 52 LYQIADGVWSHIATR 21 577.31 727.38 25 2500 53 NTAALLAEIEK 19.8 586.83 589.32 29.2 2500 54 NTAALLAEIEK 19.8 586.83 702.4 29.2 2500 55 NTAALLAEIEK 19.8 586.83 886.52 29.2 2500 56 NTVALLAEIEK 21.2 600.85 589.32 30 2500 57 NTVALLAEIEK 21.2 600.85 702.4 30 2500 58 NTVALLAEIEK 21.2 600.85 886.52 30 2500 59 QIGLPVTR 15.6 442.27 472.29 20.9 2500 60 QIGLPVTR 15.6 442.27 642.39 20.9 2500 61 QIGLPVTR 15.6 442.27 755.48 20.9 2500 62 QLAEAAGNEVPAHSLK 13.8 545.62 597.32 24 2500 63 QLAEAAGNEVPAHSLK 13.8 545.62 652.38 24 2500 64 QLAEAAGNEVPAHSLK 13.8 545.62 697.36 24 2500 65 SFDGAVYPSNGLIVR 19.2 797.92 559.32 41.2 2500 66 SFDGAVYPSNGLIVR 19.2 797.92 855.51 41.2 2500 67 SFDGAVYPSNGLIVR 19.2 797.92 1018.57 41.2 2500 68 SISTHFHDDR 10.6 405.52 413.68 19.7 2500 69 SISTHFHDDR 10.6 405.52 507.72 19.7 2500 70 SISTHFHDDR 10.6 405.52 689.3 19.7 2500 71 SVSTHFHDDR 9.2 400.85 413.68 19.5 2500 72 SVSTHFHDDR 9.2 400.85 507.72 19.5 2500 73 SVSTHFHDDR 9.2 400.85 689.3 19.5 2500 74 TSAGNVADADLAEWPGSVER 19.2 682.32 322.67 28.2 2500 75 TSAGNVADADLAEWPGSVER 19.2 682.32 644.34 28.2 2500 76 TSAGNVADADLAEWPGSVER 19.2 682.32 830.42 28.2 2500 77 TSAGNVADADLAEWPGSVER 19.2 1022.98 644.34 54 2500 78 TSAGNVADADLAEWPTSIER 20.7 701.67 351.69 28.8 2500 79 TSAGNVADADLAEWPTSIER 20.7 701.67 702.38 28.8 2500 80 TSAGNVADADLAEWPTSIER 20.7 701.67 888.46 28.8 2500 81 TSAGNVADADLAEWPTSIER 20.7 1052 702.38 55.7 2500 82 TSAGNVADADLAEWPTSVER 19.6 697 344.69 28.7 2500 83 TSAGNVADADLAEWPTSVER 19.6 697 688.36 28.7 2500 84 TSAGNVADADLAEWPTSVER 19.6 697 874.44 28.7 2500 85 TSAGNVADADLAEWPTSVER 19.6 1045 688.36 55.3 2500 86 VGGVDALR 12.8 393.73 474.27 18.2 2500 87 VGGVDALR 12.8 393.73 630.36 18.2 2500 88 VGGVDALR 12.8 393.73 687.38 18.2 2500 89 VGGVDVLR 14.8 407.74 502.3 19 2500 90 VGGVDVLR 14.8 407.74 658.39 19 2500 91 VGGVDVLR 14.8 407.74 715.41 19 2500 92 VLFGGCAVHEASR 15.1 468.24 522.24 21.6 5100 93 VLFGGCAVHEASR 15.1 468.24 595.77 21.6 5100 94 VLFGGCAVHEASR 15.1 468.24 599.29 21.6 5100 95 VLYGGCAVHELSR 15.3 487.58 543.26 22.2 2500 96 VLYGGCAVHELSR 15.3 487.58 624.79 22.2 2500 97 VLYGGCAVHELSR 15.3 487.58 641.34 22.2 2500

-   -   The other machine parameters used are as follows:     -   Scan type: MRM     -   MRM planned: yes     -   Polarity: Positive     -   Ionising source: Turbo V™ (Applied BioSystems)     -   Q1 setting: Filtering with unit resolution     -   Q3 setting: Filtering with unit resolution     -   Inter-scan pause: 5.00 msec     -   Scanning speed: 10 Da/s     -   Curtain gas: 50.00 psi     -   Cone voltage: 5500.00 V     -   Source temperature: 500.00° C.     -   Nebulising gas: 50.00 psi     -   Heating gas: 50.00 psi     -   Collision gas which induces dissociation: 9.00 psi     -   Dynamic filling: activated     -   Declustering potential (DP): 100.00 V     -   Entry potential before Q0 (EP): 6.00 V     -   Collision cell exit potential (CXP): 15 V     -   Total cycle time: 0.04 sec     -   Detection window: 120 sec

The areas obtained for each of the transitions and for each of the microorganisms studied were measured. When the areas of the transitions are greater than or equal to the positivity threshold described in TABLE 33, the detection of the transition is considered to be positive and is labelled “1” in TABLE 34. When a transition has an area less than the positivity threshold described in TABLE 33, the transition is considered non-detected and is labelled “0” in TABLE 34.

For a given peptide, when at least 3 transitions are labelled “1”, the peptide is considered as being detected.

TABLE 34 Transition number Sam165 Sam166 Sam167 Sam168 Sam169 Sam170 1 0 0 0 0 0 0 2 0 0 0 0 0 0 3 0 0 0 0 0 0 4 0 0 0 0 0 0 5 0 0 0 0 0 0 6 0 0 0 0 0 0 7 0 0 0 0 0 1 8 0 0 0 0 0 1 9 0 0 0 0 0 1 10 0 0 0 0 0 0 11 0 0 0 0 0 0 12 0 0 0 0 0 0 13 0 0 0 0 0 1 14 0 0 0 0 0 1 15 0 0 0 0 0 1 16 0 0 0 0 0 0 17 0 0 0 0 0 0 18 0 0 0 0 0 0 19 1 1 1 1 1 1 20 1 1 1 1 1 1 21 1 1 1 1 1 1 22 0 0 0 0 0 0 23 0 0 0 0 0 0 24 0 0 0 0 0 0 25 0 0 0 0 0 0 26 0 0 0 0 0 0 27 0 0 0 0 0 0 28 0 0 0 0 0 0 29 0 0 0 0 0 0 30 0 0 0 0 0 0 31 0 0 0 0 0 0 32 0 0 0 0 0 0 33 0 0 0 0 0 0 34 0 0 0 0 0 0 35 0 0 0 0 0 0 36 0 0 0 0 0 0 37 0 0 0 0 0 0 38 0 0 0 0 0 0 39 0 0 0 0 0 0 40 0 0 0 0 0 0 41 0 0 0 0 0 0 42 0 0 0 0 0 0 43 0 0 0 0 0 0 44 0 0 0 0 0 0 45 0 0 0 0 0 0 46 0 0 0 0 0 0 47 0 0 0 0 0 0 48 0 0 0 0 0 0 49 0 0 0 0 0 0 50 0 0 0 0 0 0 51 0 0 0 0 0 0 52 0 0 0 0 0 0 53 0 0 0 0 0 0 54 0 0 0 0 0 0 55 0 0 0 0 0 0 56 0 0 0 0 0 0 57 0 0 0 0 0 0 58 0 0 0 0 0 0 59 0 0 0 0 0 0 60 0 0 0 0 0 0 61 0 0 0 0 0 0 62 0 0 0 0 0 0 63 0 0 0 0 0 0 64 0 0 0 0 0 0 65 0 0 0 0 0 0 66 0 0 0 0 0 0 67 0 0 0 0 0 0 68 0 0 0 0 0 0 69 0 0 0 0 0 0 70 0 0 0 0 0 0 71 0 0 0 0 0 0 72 0 0 0 0 0 0 73 0 0 0 0 0 0 74 0 0 0 0 0 0 75 0 0 0 0 0 0 76 0 0 0 0 0 0 77 0 0 0 0 0 0 78 1 0 1 0 0 0 79 1 0 1 0 0 0 80 1 0 1 0 0 0 81 1 0 1 0 0 0 82 0 0 0 1 1 0 83 0 0 0 1 1 0 84 0 0 0 1 1 0 85 0 0 0 1 1 0 86 0 0 0 0 0 0 87 0 0 0 0 0 0 88 0 0 0 0 0 0 89 1 1 1 1 1 1 90 1 1 1 1 1 1 91 1 1 1 1 1 1 92 0 0 0 0 0 0 93 0 0 0 0 0 0 94 0 0 0 0 0 0 95 0 0 0 0 1 1 96 0 0 0 0 1 1 97 0 0 0 0 1 1

Samples Sam165 to Sam170 comprise at least one peptide which is characteristic of VIMs. The bacteria present in samples Sam165 to Sam170 therefore express a beta-lactamase which confers on them a resistance to penicillins, to cephalosporins and to carbapenems.

The detection methods described in examples 6 to 11 are particularly advantageous because they make it possible to assay a large number of peptides and at the same time to detect the presence of one or more resistance mechanisms induced by one or more carbapenemases.

Furthermore, the detection is performed in a short time, less than one hour. In fact, only the part of the gradient between 3 and 34 minutes is useful to the analysis. Furthermore, the retention times of the assayed peptides are all below 34 minutes.

In addition, the detection methods described in examples 6 to 11 are more advantageous than the molecular biology methods because they detect the product of the expression of the genes, and not the genes themselves. The detection of a resistance may not have any clinical meaning if this gene is not expressed, or it if is expressed too weakly to lead to an effective resistance. The detection of a peptide characterising a protein characteristic of a resistance mechanism does not have this disadvantage.

Surprisingly, the above examples show that it is possible to attain by mass spectrometry the sensitivity necessary for the specific detection of the existence of a mechanism of resistance to at least one antimicrobial of a microorganism contained in a sample, without employing an amplification method as is usually the case when molecular biology methods are used.

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1. A method of detecting carbapenem resistance, comprising: performing mass spectrometry on a sample to determine whether the sample includes at least one marker of resistance to at least one carbapenem; wherein: the resistance marker indicates that a microorganism expresses a protein conferring resistance to at least one carbapenem; and the resistance marker is at least one VIM peptide having any of the full-length amino acid sequences set forth in SEQ ID NOs: 314-318 and 320-346.
 2. The method according to claim 1, wherein the mass spectrometry is an MS/MS spectrometry.
 3. The method according to claim 2, wherein the MS/MS spectrometry is MRM.
 4. The method according to claim 1, wherein the resistance marker is a peptide of the protein conferring carbapenem resistance.
 5. The method according to claim 4, further comprising, before performing mass spectrometry, digesting proteins to produce peptides in the sample.
 6. The method according to claim 5, wherein the digestion is performed by an enzyme.
 7. The method according to claim 6, wherein the enzyme is trypsin.
 8. The method according to claim 1, wherein the at least one VIM peptide has any of the full-length amino acid sequences set forth in SEQ ID NOs: 316, 318, 321, 341, 342, 344, and
 346. 9. The method according to claim 1, further comprising performing mass spectometry on the sample to determine whether the sample includes NDM, GES, IMP, IND, SME, and OXA.
 10. A method of detecting carbapenem resistance, comprising: performing mass spectrometry on a sample to determine whether the sample includes at least one marker of resistance to at least one carbapenem; wherein: the resistance marker indicates that a microorganism expresses a protein conferring resistance to at least one carbapenem; and the resistance marker is at least one OXA peptide having any of the full-length amino acid sequences set forth in SEQ ID NOs: 509-523, 525-572, 574-604, 606-618, 620-696, 698-1077, and 1098-1109.
 11. The method according to claim 10, wherein the mass spectrometry is an MS/MS spectrometry.
 12. The method according to claim 11, wherein the MS/MS spectrometry is MRM.
 13. The method according to claim 10, wherein the resistance marker is a peptide of the protein conferring carbapenem resistance.
 14. The method according to claim 13, further comprising, before performing mass spectrometry, digesting proteins to produce peptides in the sample.
 15. The method according to claim 14, wherein the digestion is performed by an enzyme.
 16. The method according to claim 15, wherein the enzyme is trypsin.
 17. The method according to claim 10, wherein the at least one OXA peptide has any of the full-length amino acid sequences set forth in SEQ ID NOs: 509, 510, 512, 513, 514, 515, 516, 517, 518, 519, 520, 521, 522, 523, 525, 526, 528, 530, 531, 532, 533, 534, 535, 536, 537, 538, 539, 540, 541, 542, 543, 544, 545, 546, 547, 548, 549, 550, 551, 552, 553, 554, 555, 556, 557, 558, 559, 560, 561, 562, 563, 564, 565, 566, 567, 571, 572, 574, 575, 576, 577, 578, 580, 581, 583, 584, 586, 587, 588, 589, 590, 591, 593, 594, 595, 596, 597, 598, 599, 600, 601, 602, 604, 606, 607, 609, 611, 612, 613, 614, 615, 616, 618, 620, 622, 623, 624, 625, 626, 627, 632, 633, 635, 636, 637, 638, 639, 640, 641, 642, 643, 645, 648, 649, 651, 652, 653, 654, 655, 656, 659, 660, 664, 665, 666, 667, 669, 670, 672, 673, 674, 675, 676, 677, 678, 679, 680, 681, 685, 686, 687, 688, 689, 690, 691, 692, 693, 694, 696, 698, 699, 700, 701, 702, 703, 706, 707, 710, 714, 717, 719, 720, 722, 725, 726, 727, 728, 729, 732, 735, 736, 737, 738, 740, 741, 743, 744, 745, 746, 747, 748, 749, 750, 751, 752, 753, 754, 755, 756, 757, 759, 760, 762, 763, 766, 767, 768, 769, 770, 771, 773, 774, 775, 776, 777, 778, 779, 780, 781, 782, 783, 785, 786, 787, 788, 789, 790, 792, 793, 794, 795, 796, 797, 798, 799, 800, 801, 803, 804, 805, 806, 807, 809, 810, 811, 812, 813, 814, 815, 818, 821, 822, 824, 825, 826, 827, 828, 829, 830, 831, 832, 833, 834, 835, 836, 837, 838, 840, 841, 842, 844, 845, 846, 847, 848, 849, 850, 851, 853, 854, 855, 856, 857, 858, 859, 860, 861, 862, 865, 866, 867, 868, 869, 871, 874, 875, 876, 877, 878, 879, 880, 881, 882, 883, 884, 885, 886, 887, 888, 889, 890, 891, 892, 893, 894, 895, 896, 897, 898, 899, 900, 901, 902, 903, 904, 905, 906, 907, 908, 909, 910, 912, 913, 914, 918, 920, 921, 922, 923, 928, 930, 932, 935, 936, 937, 938, 939, 940, 941, 942, 943, 944, 945, 946, 947, 948, 949, 950, 951, 953, 954, 955, 956, 958, 961, 962, 963, 964, 967, 968, 970, 972, 973, 974, 975, 976, 977, 978, 979, 980, 981, 982, 983, 984, 985, 986, 988, 990, 992, 993, 994, 995, 996, 997, 998, 1000, 1001, 1003, 1004, 1005, 1008, 1009, 1011, 1012, 1013, 1014, 1015, 1018, 1019, 1020, 1022, 1024, 1025, 1026, 1027, 1028, 1030, 1031, 1034, 1036, 1041, 1042, 1044, 1045, 1046, 1048, 1049, 1050, 1052, 1053, 1054, 1058, 1059, 1060, 1062, 1063, 1064, 1067, 1068, 1069, 1070, 1071, 1072, 1073, 1074, 1075, 1076, 1098, 1099, 1100, 1101, 1102, 1103, 1104, 1105, 1106, 1107, 1108, and
 1109. 18. The method according to claim 10, wherein the at least one OXA peptide has any of the full-length amino acid sequences set forth in SEQ ID NOs: 510, 512, 513, 514, 520, 521, 522, 523, 525, 530, 532, 537, 541, 542, 543, 544, 545, 546, 547, 548, 549, 550, 551, 552, 556, 557, 558, 559, 560, 561, 562, 574, 581, 582, 583, 584, 596, 597, 598, 599, 600, 601, 602, 607, 609, 632, 633, 635, 636, 649, 655, 656, 667, 674, 675, 689, 690, 698, 714, 719, 720, 722, 727, 729, 741, 746, 748, 750, 751, 752, 755, 756, 757, 763, 767, 768, 772, 775, 781, 782, 790, 792, 793, 794, 795, 796, 797, 798, 801, 809, 811, 812, 813, 814, 824, 832, 834, 837, 838, 847, 851, 853, 854, 855, 856, 857, 858, 859, 860, 862, 868, 869, 870, 874, 875, 876, 877, 879, 880, 881, 882, 894, 895, 898, 902, 903, 904, 906, 907, 908, 912, 913, 914, 920, 922, 923, 937, 938, 939, 945, 946, 948, 949, 950, 951, 954, 956, 962, 964, 967, 969, 971, 972, 974, 975, 979, 980, 985, 988, 990, 993, 994, 995, 996, 997, 1000, 1001, 1003, 1004, 1005, 1011, 1013, 1015, 1018, 1019, 1027, 1030, 1034, 1035, 1036, 1042, 1048, 1052, 1058, 1060, 1070, 1098, 1099, 1100, 1101, 1102, 1103, 1104, 1105, 1106, 1107, 1108, and
 1109. 19. The method according to claim 10, wherein the at least one OXA peptide has any of the full-length amino acid sequences set forth in SEQ ID NOs: 1098, 1100, 1102, 1103, 1104, 1105, 1107, 1108, and
 1109. 20. The method according to claim 10, further comprising performing mass spectometry on the sample to determine whether the sample includes NDM, GES, IMP, IND, SME, and VIM. 